ccmx annual activity report 2007

ANNUAL REPORT 2007

CCMX was created at the beginning of

2006 with the aim of linking the excellent

academic research in the ETH domain to

the needs of industry. Three Educational

and Research Units (ERUs) were created

in areas of key importance to the eco-

nomy :

• Surface, coatings and particles

engineering (SPERU);

• Materials for the life sciences

(MatLife);

• Materials for micro- and nanosystems

(MMNS);

An Analytical Platform (NNMC) was

also created to develop and promote

activities in nano- and microscale

materials characterisation.

The first flagship projects started to-

wards the end of 2006 and are already,

after just over a year of work, starting to

deliver important results. Highlights

from these projects, involving 12 indus-

trial partners and over 150 scientists

and engineers from more than 60 labo-

ratories, are shown in the pages of this

report.

As a result of a detailed consultation

with the industrial sector, a new ERU

in metallurgy (MERU) was launched at

the end of 2007.

The focus of the Centre is now on

strengthening the role of industry in the

research carried out by CCMX. The new

call for proposals initiated at the end of

2007 is focussed on bridging the gap

between the fundamental research sup-

ported by the Swiss National Science

foundation and «near to market» research

funded by the CTI. The new projects will

be jointly funded by CCMX funds and

pre-competitive consortia from the

industry. Club CCMX has been set-up

to offer companies another alternative

to be involved in CCMX activities.

CCMX is growing fast. The exciting results

of on-going projects, the level of the

newly funded projects to start in 2008,

and the growing network of industrial

partners are all very promising. CCMX

will be a strong force in materials research

for Switzerland in the coming years.

Annual Report 2007 Annual Report 2007

CCMX was created at the beginning of

2006 with the aim of linking the excellent

academic research in the ETH domain to

the needs of industry. Three Educational

and Research Units (ERUs) were created

in areas of key importance to the eco-

nomy :

• Surface, coatings and particles

engineering (SPERU);

• Materials for the life sciences

(MatLife);

• Materials for micro- and nanosystems

(MMNS);

An Analytical Platform (NNMC) was

also created to develop and promote

activities in nano- and microscale

materials characterisation.

The first flagship projects started to-

wards the end of 2006 and are already,

after just over a year of work, starting to

deliver important results. Highlights

from these projects, involving 12 indus-

trial partners and over 150 scientists

and engineers from more than 60 labo-

ratories, are shown in the pages of this

report.

As a result of a detailed consultation

with the industrial sector, a new ERU

in metallurgy (MERU) was launched at

the end of 2007.

The focus of the Centre is now on

strengthening the role of industry in the

research carried out by CCMX. The new

call for proposals initiated at the end of

2007 is focussed on bridging the gap

between the fundamental research sup-

ported by the Swiss National Science

foundation and «near to market» research

funded by the CTI. The new projects will

be jointly funded by CCMX funds and

pre-competitive consortia from the

industry. Club CCMX has been set-up

to offer companies another alternative

to be involved in CCMX activities.

CCMX is growing fast. The exciting results

of on-going projects, the level of the

newly funded projects to start in 2008,

and the growing network of industrial

partners are all very promising. CCMX

will be a strong force in materials research

for Switzerland in the coming years.

research with matching funds from the

ETH domain and will have a direct say in

the advancement of the projects within the

chosen thematic area.

In addition to the development of

technologies and know-how, the training

of Ph.D. students in a field of direct interest

to the companies adds significant value

to this programme. The CCMX Research

Programme offers direct access to

the best Swiss expertise in selected

thematic areas of materials science.

For smaller companies not able to fund

research tickets, Club CCMX offers access

to the networking and training activities of

CCMX. More information is provided in the

article entitled “Perspectives for 2008”.

CCMX federates the strengths of four ETH

Domain institutions (EPFL, ETH Zurich,

EMPA, PSI) and of CSEM, and involves the

active participation of partners from industry,

from industrial associations and from Swiss

universities. The Centre is headed by a

Steering Committee comprising members

from EPFL (chair), ETH Zurich, PSI, Empa,

CSEM and industry.

At the core of the Centre’s activities are

ERUs – Education and Research Units –

and an Analytical Platform. The ERUs offer

programmes of research and education,

including technology transfer, in targeted

fields of activity identified together with the

Swiss industry :

– surface, coatings and particles engine-

ering (SPERU)

– materials for the life sciences (MatLife)

– materials for micro- and nanosystems

(MMNS)

– metallurgy (MERU)

Closely linked to these ERUs is an Analyti-

cal Platform developing and promoting

activities in nano- and microscale mater-

ials characterisation for industry and

academia (NMMC).

The Centre is currently funding 27 projects

involving 12 industrial partners, over 150

scientists and engineers and more than

60 laboratories from 7 institutions (see the

detailed list of projects on page 30). A call

for new proposals is currently underway

and will lead to the funding of new projects

from spring 2008. CCMX concentrates on

pre-competitive research and thus aims to

strongly and positively influence this area in

Switzerland.

Each CCMX funded project includes at

least two institutions and very often one or

more industrial partners. This multi-partner

project approach brings together the best

competencies from all over Switzerland in

specific materials science related domains.

A wide range of continuing education is

on offer at CCMX. Courses, seminars and

workshops are regularly organised by the

ERUs and the platform (more details can

be found on page 24). Topics are chosen

based on the actual needs of the targeted

audiences (PhD students, engineers,

scientists from industry and/or academia).

These continuing education initiatives

attracted more than 230 participants from

industry and academia in 2007 and will

continue in 2008. Some new modules such

as short courses, summer schools and

travelling lab workshops will be added to

the offer in 2008.

The interactions that CCMX maintains with

the industry are decisive in the process of

technology and knowledge transfer. By

involving several institutions and one or

more industrial partner in each project,

CCMX ensures access to fundamental

and applied know-how.

The industrial liaison programme of CCMX

is a means for both large and small compa-

nies to have access to the technology and

the knowledge developed within the

Centre. Companies have two options to be

involved in CCMX. They can either purchase

research tickets or become members of

Club CCMX. For details please see the

article «Perspectives 2008» on page 26.

CCMX’s outreach activities and industrial

liaison programme are perfect opportuni-

ties for the industry to communicate its

needs in terms of research and education.

CCMX aims to strongly and positively

influence materials science in Switzerland

by building a Swiss reservoir of expertise

in the field of materials science. It builds

bridges between the scientific and indus-

trial communities and addresses targeted

specific needs with particular emphasis on

developments of interest for the applica-

tions of tomorrow.

CCMX, through its four Education &

Research Units (ERUs), currently focuses

on the 9 thematic areas presented in detail

in the coming pages. New pre-competitive

research projects will be launched in 2008.

The active participation of industrial partners

is considered as essential to CCMX’s

mission of linking academia and industry.

To this end a common model for industrial

liaison is being implemented. CCMX is

establishing research consortia bringing

together companies interested in the same

thematic area.

With the purchase of research tickets in

a chosen thematic area, industry consortia

will share the costs of pre-competitive

Morphology of two different SiO2 -doping level of SnO2 nanostructures used for sensor applications. Low SiO2 contents (left) lead to slightly aggregated nanostructures and small neck size/angle with high sensitivity; high SiO2 contents (right) lead to isolated SnO2 crystals with no sensitivity, due to the high resistance of SiO2 between SnO2 crystals (ETH Zurich, PSI & Empa).

research with matching funds from the

ETH domain and will have a direct say in

the advancement of the projects within the

chosen thematic area.

In addition to the development of

technologies and know-how, the training

of Ph.D. students in a field of direct interest

to the companies adds significant value

to this programme. The CCMX Research

Programme offers direct access to

the best Swiss expertise in selected

thematic areas of materials science.

For smaller companies not able to fund

research tickets, Club CCMX offers access

to the networking and training activities of

CCMX. More information is provided in the

article entitled “Perspectives for 2008”.

CCMX federates the strengths of four ETH

Domain institutions (EPFL, ETH Zurich,

EMPA, PSI) and of CSEM, and involves the

active participation of partners from industry,

from industrial associations and from Swiss

universities. The Centre is headed by a

Steering Committee comprising members

from EPFL (chair), ETH Zurich, PSI, Empa,

CSEM and industry.

At the core of the Centre’s activities are

ERUs – Education and Research Units –

and an Analytical Platform. The ERUs offer

programmes of research and education,

including technology transfer, in targeted

fields of activity identified together with the

Swiss industry :

– surface, coatings and particles engine-

ering (SPERU)

– materials for the life sciences (MatLife)

– materials for micro- and nanosystems

(MMNS)

– metallurgy (MERU)

Closely linked to these ERUs is an Analyti-

cal Platform developing and promoting

activities in nano- and microscale mater-

ials characterisation for industry and

academia (NMMC).

The Centre is currently funding 27 projects

involving 12 industrial partners, over 150

scientists and engineers and more than

60 laboratories from 7 institutions (see the

detailed list of projects on page 30). A call

for new proposals is currently underway

and will lead to the funding of new projects

from spring 2008. CCMX concentrates on

pre-competitive research and thus aims to

strongly and positively influence this area in

Switzerland.

Each CCMX funded project includes at

least two institutions and very often one or

more industrial partners. This multi-partner

project approach brings together the best

competencies from all over Switzerland in

specific materials science related domains.

A wide range of continuing education is

on offer at CCMX. Courses, seminars and

workshops are regularly organised by the

ERUs and the platform (more details can

be found on page 24). Topics are chosen

based on the actual needs of the targeted

audiences (PhD students, engineers,

scientists from industry and/or academia).

These continuing education initiatives

attracted more than 230 participants from

industry and academia in 2007 and will

continue in 2008. Some new modules such

as short courses, summer schools and

travelling lab workshops will be added to

the offer in 2008.

The interactions that CCMX maintains with

the industry are decisive in the process of

technology and knowledge transfer. By

involving several institutions and one or

more industrial partner in each project,

CCMX ensures access to fundamental

and applied know-how.

The industrial liaison programme of CCMX

is a means for both large and small compa-

nies to have access to the technology and

the knowledge developed within the

Centre. Companies have two options to be

involved in CCMX. They can either purchase

research tickets or become members of

Club CCMX. For details please see the

article «Perspectives 2008» on page 26.

CCMX’s outreach activities and industrial

liaison programme are perfect opportuni-

ties for the industry to communicate its

needs in terms of research and education.

CCMX aims to strongly and positively

influence materials science in Switzerland

by building a Swiss reservoir of expertise

in the field of materials science. It builds

bridges between the scientific and indus-

trial communities and addresses targeted

specific needs with particular emphasis on

developments of interest for the applica-

tions of tomorrow.

CCMX, through its four Education &

Research Units (ERUs), currently focuses

on the 9 thematic areas presented in detail

in the coming pages. New pre-competitive

research projects will be launched in 2008.

The active participation of industrial partners

is considered as essential to CCMX’s

mission of linking academia and industry.

To this end a common model for industrial

liaison is being implemented. CCMX is

establishing research consortia bringing

together companies interested in the same

thematic area.

With the purchase of research tickets in

a chosen thematic area, industry consortia

will share the costs of pre-competitive

Morphology of two different SiO2 -doping level of SnO2 nanostructures used for sensor applications. Low SiO2 contents (left) lead to slightly aggregated nanostructures and small neck size/angle with high sensitivity; high SiO2 contents (right) lead to isolated SnO2 crystals with no sensitivity, due to the high resistance of SiO2 between SnO2 crystals (ETH Zurich, PSI & Empa).

wo projects initiated early 2007 are

currently underway in this thematic

area. The first one «Nanocrystalline

ceramic thin film coating without sintering

(NANCER)» involves five research groups

from ETH Zurich (Prof. L. Gauckler & Prof.

S. Pratsinis), EMPA (Dr. T. Graule) and PSI

(Dr. T. Lippert & Dr. K. Conder). The thermal

stability of nanocrystalline thin films inte-

grated on silicon chip-sized devices is

quantified in order to enable intermediate

to high temperature applications such as

with gas sensors and micro-solid oxide

fuel cells.

Those high functionality films are manufac-

tured through novel fabrication techniques

without the need for traditional sintering

treatment. Six deposition techniques –

spray pyrolysis, pulsed laser deposition,

direct aerosol deposition, metal-organic

chemical vapour deposition, RF sputtering

and combustion chemical vapour deposi-

tion – have been altered to enable the

preparation of ceramic thin films with

a range of selected thermal, electrical,

electrochemical and magnetic properties.

Yttria-stabilized zirconia thin films have

been produced using all the above tech-

niques and applied as electrolyte thin film

for solid oxide fuel cells, providing for the

first time indications on method-dependent

properties, i.e. the relationship between

microstructure and electrical conductivity.

Characterisation techniques for such films

have been implemented including (1) the

set-up of a new test platform for electro-

chemical properties enabling the discrimi-

nation between the ionic and electronic

contributions to conductivity and (2) the

set-up of a device for measuring electrical

properties at high temperature. Macro- and

micro- gas sensors were produced by

direct aerosol deposition of thin layers of

SnO2 nanoparticles where small crystal size

was preserved, therefore providing higher

sensor performance.

The second project in this thematic area

deals with novel physical colours made-up

through the unique arrangement of

non-spherical nanosized particles in an

inorganic or organic matrix for applications

in safety or decorative surfaces. Those

completely novel spectral characteristics

are based on zero order diffraction - ZOD.

The «Zero order nano optical pigments

(ZONOP)» project is lead by Dr. A. Stuck at

CSEM and involves PSI’s Dr. R. Morf.

Theoretical simulations were performed to

understand the effects of the shrinkage of

the full structure length of a subwavelength

on the reflection and transmission spectra.

The first tests performed with structures of

10, 40, 80, and infinite number of periods

are promising. The reflection peak is still

present in structures of only 10 periods

whereas the intensity decreases down by

a factor of only 50 %. Those subwavelength

structures do not lose their colour effect

by reducing their size down to a few micro-

meters. As an example, a typical ZOD

structure with a period of 360 nm exhibits a

strong reflection (~100 %) in the green with

an infinite number of periods. By reducing

the size of the pigment down to 10 periods,

which means to a pixel of 3.6 microns, the

green reflection peak is still centred at the

same wavelength but its intensity is de-

creased to 50 %. Such results were antici-

pated but never simulated before.

Vacuum-based thin-film technologies are

vital for creating hard, resistant surfaces for

electronics and tooling applications. Many

of the underlying basic processes are still

not yet elucidated and important production

problems remain unsolved. In chemical va-

pour deposition coating performed at 800 °C

and above, residual tensile stress is built up

caused by the different thermal expansion

coefficients during cooling. Multi-layered

and nanostructured coatings with a built-in

high compressive stress may be an answer.

Thin, transparent, inorganic coatings on

polymers are alternatives to heavy, brittle

and rigid glass for food and pharmaceutical

packaging. These thin film composites are

inherently flexible and, moreover, enable

cost-effective roll-to-roll production.

Exceptional gas-barrier performance is ex-

pected from artificially layered nanostruc-

tured materials. Interesting candidates for

avoiding premature failure are hybrids based

on metal-oxide layers combined with UV-

curable organosilanes and hyperbranched

polymer precursors, which substantially

reduce in shrinkage stresses as a result of

their particular network formation mecha-

nisms. On the other hand, patterned electro-

des with tailored conductivity can be made

with a proven but expensive technology.

Novel approaches should be explored and

combined with the barrier function. In the

field of organic electronics and thin films,

solar cell devices with transparent electrodes

compatible with continuous production are

required.

Nanoscale gratings, with periods less than

500 nm combined with thin (less than 200

nm) dielectric layers also called zero-order

diffraction (ZOD) devices act as highly

effective colour filters at specific wavelengths.

Strong colour and size effects are expected

if the pigment size is of the order of a few

grating periods or less, i.e. of about 1 micron.

These effects are currently neither understood

theoretically nor have they been verified

experimentally.

Pulsed Laser Deposition of ceramic thin films (PSI, ETH Zurich & EMPA). La0.6 Sr0.4 Co0.2 Fe0.8 O3 (LSCF) thin films deposited on silicon nitride by cathode spray pyrolysis (ETH Zurich, PSI & Empa).

Fabrication process of Zero Order Diffraction structures (CSEM & PSI).

400 µm

wo projects initiated early 2007 are

area. The first one «Nanocrystalline

ceramic thin film coating without sintering

(NANCER)» involves five research groups

from ETH Zurich (Prof. L. Gauckler & Prof.

S. Pratsinis), EMPA (Dr. T. Graule) and PSI

(Dr. T. Lippert & Dr. K. Conder). The thermal

stability of nanocrystalline thin films inte-

grated on silicon chip-sized devices is

quantified in order to enable intermediate

to high temperature applications such as

with gas sensors and micro-solid oxide

fuel cells.

Those high functionality films are manufac-

tured through novel fabrication techniques

without the need for traditional sintering

treatment. Six deposition techniques –

spray pyrolysis, pulsed laser deposition,

direct aerosol deposition, metal-organic

chemical vapour deposition, RF sputtering

and combustion chemical vapour deposi-

tion – have been altered to enable the

preparation of ceramic thin films with

a range of selected thermal, electrical,

electrochemical and magnetic properties.

Yttria-stabilized zirconia thin films have

been produced using all the above tech-

niques and applied as electrolyte thin film

for solid oxide fuel cells, providing for the

first time indications on method-dependent

properties, i.e. the relationship between

microstructure and electrical conductivity.

Characterisation techniques for such films

have been implemented including (1) the

set-up of a new test platform for electro-

chemical properties enabling the discrimi-

nation between the ionic and electronic

contributions to conductivity and (2) the

set-up of a device for measuring electrical

properties at high temperature. Macro- and

micro- gas sensors were produced by

direct aerosol deposition of thin layers of

SnO2 nanoparticles where small crystal size

was preserved, therefore providing higher

sensor performance.

The second project in this thematic area

deals with novel physical colours made-up

through the unique arrangement of

non-spherical nanosized particles in an

inorganic or organic matrix for applications

in safety or decorative surfaces. Those

completely novel spectral characteristics

are based on zero order diffraction - ZOD.

The «Zero order nano optical pigments

(ZONOP)» project is lead by Dr. A. Stuck at

CSEM and involves PSI’s Dr. R. Morf.

Theoretical simulations were performed to

understand the effects of the shrinkage of

the full structure length of a subwavelength

on the reflection and transmission spectra.

The first tests performed with structures of

10, 40, 80, and infinite number of periods

are promising. The reflection peak is still

present in structures of only 10 periods

whereas the intensity decreases down by

a factor of only 50 %. Those subwavelength

structures do not lose their colour effect

by reducing their size down to a few micro-

meters. As an example, a typical ZOD

structure with a period of 360 nm exhibits a

strong reflection (~100 %) in the green with

an infinite number of periods. By reducing

the size of the pigment down to 10 periods,

which means to a pixel of 3.6 microns, the

green reflection peak is still centred at the

same wavelength but its intensity is de-

creased to 50 %. Such results were antici-

pated but never simulated before.

Vacuum-based thin-film technologies are

vital for creating hard, resistant surfaces for

electronics and tooling applications. Many

of the underlying basic processes are still

not yet elucidated and important production

problems remain unsolved. In chemical va-

pour deposition coating performed at 800 °C

and above, residual tensile stress is built up

caused by the different thermal expansion

coefficients during cooling. Multi-layered

and nanostructured coatings with a built-in

high compressive stress may be an answer.

Thin, transparent, inorganic coatings on

polymers are alternatives to heavy, brittle

and rigid glass for food and pharmaceutical

packaging. These thin film composites are

inherently flexible and, moreover, enable

cost-effective roll-to-roll production.

Exceptional gas-barrier performance is ex-

pected from artificially layered nanostruc-

tured materials. Interesting candidates for

avoiding premature failure are hybrids based

on metal-oxide layers combined with UV-

curable organosilanes and hyperbranched

polymer precursors, which substantially

reduce in shrinkage stresses as a result of

their particular network formation mecha-

nisms. On the other hand, patterned electro-

des with tailored conductivity can be made

with a proven but expensive technology.

Novel approaches should be explored and

combined with the barrier function. In the

field of organic electronics and thin films,

solar cell devices with transparent electrodes

compatible with continuous production are

required.

Nanoscale gratings, with periods less than

500 nm combined with thin (less than 200

nm) dielectric layers also called zero-order

diffraction (ZOD) devices act as highly

effective colour filters at specific wavelengths.

Strong colour and size effects are expected

if the pigment size is of the order of a few

grating periods or less, i.e. of about 1 micron.

These effects are currently neither understood

theoretically nor have they been verified

experimentally.

Pulsed Laser Deposition of ceramic thin films (PSI, ETH Zurich & EMPA). La0.6 Sr0.4 Co0.2 Fe0.8 O3 (LSCF) thin films deposited on silicon nitride by cathode spray pyrolysis (ETH Zurich, PSI & Empa).

Fabrication process of Zero Order Diffraction structures (CSEM & PSI).

400 µm

ne project entitled «Smart Functional

Foams» and initiated early 2007 is

area. A direct foaming method is applied

for producing foams with tailored porosity,

pore size distribution and pore connectivity

using modified colloidal particles as foam

stabilizers. The project gathers four research

groups originating from ETH Zurich (Prof. L.

Gauckler, Prof. P. Ermanni & Prof. J. Löffler)

and from EPFL (Prof. D. Pioletti).

Preparation of stable foams from all three

classes of particulate materials – ceramic,

metal or polymer – was achieved; this in-

cludes the challenge of manipulating highly

inflammable metallic particles. A method

for creating open pores larger than 100 µm

in ceramic foams with controlled average

pore size and pore openings was imple-

mented. The growth of bone-growing cells

for potential application as scaffold materials

is currently under study. The whole proces-

sing chain for preparing dried foams from

titanium and nickel / titanium nanoparticles

was set-up in an oxygen free atmosphere.

Oxide content as low as 2 mass-percent in

the dry porous material and average pore

sizes of less than 50 µm is quite promising.

Polyvinylidene fluoride (PVDF) particles are

used as starting materials for producing

materials with a closed cell structure.

To obtain a partially open-cell structure

an emulsion-based process is used. Piezo-

electric properties of both types of struc-

tures made of PVDF and other polymers

are currently being tested.

A major advantage of this novel foaming

technique is the enhanced foam stability in

the wet state, allowing for a better control

of the foam microstructure. The method is

very versatile and can be used to produce

porous materials out of ceramics, metals,

polymers and composites. A wide variety

of foam products may therefore be foreseen.

Porous scaffolds for hard tissue repair could

be produced from inert biocompatible ma-

terials, biocompatible bioactive materials or

from bioresorbable materials. Titanium- or

magnesium-based foams have many po-

tential applications due to their outstanding

mechanical properties in combination with

a low density and high chemical resistance.

Superelastic foams could be created by

using shape memory effect above transition

temperature, i.e. using an alloy with the

transition temperature below working

temperature. Shape-memory foams could

be designed by using shape memory effect

below transition temperature, i.e. using an

alloy with a transition temperature above

working temperature. Electrically-charged

polymeric foams represent promising piezo-

electric transducers for monitoring/actu-

ating soft matter. Carbon nanotube foam

actuators represent the logical extension

of proven two-dimensional actuators based

on bucky papers to three-dimensional active

structures.

Porous structure made from a ceramic particle-stabilized foam (ETH Zurich & EPFL).

Open porous ceramic particle-stabilized foams (ETH Zurich & EPFL).

ne project entitled «Smart Functional

Foams» and initiated early 2007 is

area. A direct foaming method is applied

for producing foams with tailored porosity,

pore size distribution and pore connectivity

using modified colloidal particles as foam

stabilizers. The project gathers four research

groups originating from ETH Zurich (Prof. L.

Gauckler, Prof. P. Ermanni & Prof. J. Löffler)

and from EPFL (Prof. D. Pioletti).

Preparation of stable foams from all three

classes of particulate materials – ceramic,

metal or polymer – was achieved; this in-

cludes the challenge of manipulating highly

inflammable metallic particles. A method

for creating open pores larger than 100 µm

in ceramic foams with controlled average

pore size and pore openings was imple-

mented. The growth of bone-growing cells

for potential application as scaffold materials

is currently under study. The whole proces-

sing chain for preparing dried foams from

titanium and nickel / titanium nanoparticles

was set-up in an oxygen free atmosphere.

Oxide content as low as 2 mass-percent in

the dry porous material and average pore

sizes of less than 50 µm is quite promising.

Polyvinylidene fluoride (PVDF) particles are

used as starting materials for producing

materials with a closed cell structure.

To obtain a partially open-cell structure

an emulsion-based process is used. Piezo-

electric properties of both types of struc-

tures made of PVDF and other polymers

are currently being tested.

A major advantage of this novel foaming

technique is the enhanced foam stability in

the wet state, allowing for a better control

of the foam microstructure. The method is

very versatile and can be used to produce

porous materials out of ceramics, metals,

polymers and composites. A wide variety

of foam products may therefore be foreseen.

Porous scaffolds for hard tissue repair could

be produced from inert biocompatible ma-

terials, biocompatible bioactive materials or

from bioresorbable materials. Titanium- or

magnesium-based foams have many po-

tential applications due to their outstanding

mechanical properties in combination with

a low density and high chemical resistance.

Superelastic foams could be created by

using shape memory effect above transition

temperature, i.e. using an alloy with the

transition temperature below working

temperature. Shape-memory foams could

be designed by using shape memory effect

below transition temperature, i.e. using an

alloy with a transition temperature above

working temperature. Electrically-charged

polymeric foams represent promising piezo-

electric transducers for monitoring/actu-

ating soft matter. Carbon nanotube foam

actuators represent the logical extension

of proven two-dimensional actuators based

on bucky papers to three-dimensional active

structures.

Porous structure made from a ceramic particle-stabilized foam (ETH Zurich & EPFL).

Open porous ceramic particle-stabilized foams (ETH Zurich & EPFL).

novel vaccine and immunotherapy

technology by designing materials

exhibiting bio-functional and immuno-

functional capabilities is being developed

by a team led by EPFL (Prof. J. Hubbell). The

team also involves other colleagues from

EPFL (Prof. M. Swartz), from a Swiss company

(SurfaceSolutionS AG) and consultants from

another company. Specifically, polymer

nanoparticle formulations, following intrader-

mal injection, should target the draining

lymph nodes. Furthermore a plug-and-play

scheme to functionalise these nanoparticles

with antigen will be set-up. The biophysical

phenomenon of interstitial flow which can

direct ultra-small antigen-bearing nanoparti-

cles into the lymphatics and draining nodes,

where dendritic cells reside in highest number,

was demonstrated. Moreover materials

surface biofunctionality can be exploited to

activate complement in situ to generate a

danger signal adjuvant. The achieved efforts

span from the synthesis of the functionalised

nanoparticles toward to the demonstration

of strong and sustained antigen-specific

cellular and humoral immunity in mice.

The PAPAMOD project led by Prof. P. Renaud

(EPFL) aims to develop novel methods for

surface modification and investigation of cell-

particles interaction for superparamagnetic

nanoparticles. The project further involves

researchers from EPFL (Prof. J. Hubbell,

Dr. A. Petri-Fink) and CSEM (Dr. H. Knapp).

Nanosized superparamagnetic iron oxide

particles (SPIONs) will be coated with bio-

logical molecules and classified regarding

their physical and chemical properties using

a novel technique based on microfluidics.

The particles should help evaluate the

uptake mechanisms used by cells from the

membrane toward the nucleus.

Superparamagnetic nanoparticles were

functionalised for molecular imaging and

for protein separation inside living cells.

Colloidal stability of dispersions of particles

exhibiting different polymer coatings was

evaluated with regard to cellular uptake by

HeLa cells. Already minor modifications of

the nanoparticles surface lead to an altered

stability, uptake, and toxicity. The optimal

cell culture medium should therefore be

individually determined depending on the

particle surface modification. The pathway

of nanoparticles functionalised with organelle-

targeting peptides was identified from the

living cell membrane towards the nucleus.

A first microfluidics device prototype enabling

continuous multi-step functionalisation of

particles has been tested. It is currently

adapted to submicron and micron-sized

particles but work is in progress for develo-

ping a device suitable for continuous func-

tionnalisation of nanosized particles. The

development of a device suited to classifi-

cation of particles regarding their physical

and chemical properties is also underway.

Demand for novel therapeutic or immuno-

genic functional groups or molecules

designed for low molecular weight and

biomacromolecular pharmaceuticals is

increasing. They should act as delivery

systems capable of protecting, transporting,

and selectively depositing those therapeutic

agents at their sites of action. In the field of

magnetic resonance imaging multifunctional

particles are needed in the future. They will

need to fulfil several requirements : chemical

stability under physiological conditions and

sufficient circulation time in vivo; low level of

non-specific protein adsorption from blood

plasma to prevent fast clearance from the

blood stream; presentation of functional bio-

ligands in order to actively target specific

cells and tissue. Of particular interest is the

combination of imaging with the targeted

delivery of therapeutic agents, thus increasing

the safety and efficiency of medical treat-

ment protocols. Such approaches are still

at the research stage, but show high po-

tential for major breakthroughs in medicine.

Examples include the development of com-

posite particles that contain both drug and

contrast agents and allow for site-specific

release of therapeutics upon activation.

The development of a platform for the repro-

ducible, multifunctional, and flexible surface

derivatisation of nanoparticles suitable to

investigate cell-nanoparticle interactions in

living systems and biochemical interaction

is another long-term goal of this thematic

area. This platform should enable (a) the

reproducible and straightforward surface

derivatisation of magnetic particles, (b) the

creation of a particle library, (c) the principal

understanding of the properties of complex

nanoparticles in a physiological environment,

(d) the correlation of material properties to

their biological effects, and (e) the proof of

principle for the identification of the interaction

partners. Both, industry and academia will

gain from the availability of such a device

for systems biology and from the investigation

of cell-nanoparticle interactions. One of the

most important questions for toxicologists

is the quantification of nanoparticles that

have been taken up by cells or organisms.

This question has not been answered today.

Sophisticated applications of superpara-

magnetic particles will be tacked in a further

step. They include magnetic enhanced trans-

fection, treatment of tumours by hyperthermia,

targeted drug delivery and target fishing for

solving problems related to systems biology.

Ph.D. student Sai Reddy of EPFL was awarded the “KPMG Tomorrow’s Market Award” 2007 (Project “Immunofunc-tional Nanoparticles”).

Flow-through particle processor for high yield and high quality functionalisation of particles (EPFL & CSEM).

Nucleus targeting by functionalised superparamagnetic iron oxide nanoparticles (EPFL & CSEM).

novel vaccine and immunotherapy

technology by designing materials

exhibiting bio-functional and immuno-

functional capabilities is being developed

by a team led by EPFL (Prof. J. Hubbell). The

team also involves other colleagues from

EPFL (Prof. M. Swartz), from a Swiss company

(SurfaceSolutionS AG) and consultants from

another company. Specifically, polymer

nanoparticle formulations, following intrader-

mal injection, should target the draining

lymph nodes. Furthermore a plug-and-play

scheme to functionalise these nanoparticles

with antigen will be set-up. The biophysical

phenomenon of interstitial flow which can

direct ultra-small antigen-bearing nanoparti-

cles into the lymphatics and draining nodes,

where dendritic cells reside in highest number,

was demonstrated. Moreover materials

surface biofunctionality can be exploited to

activate complement in situ to generate a

danger signal adjuvant. The achieved efforts

span from the synthesis of the functionalised

nanoparticles toward to the demonstration

of strong and sustained antigen-specific

cellular and humoral immunity in mice.

The PAPAMOD project led by Prof. P. Renaud

(EPFL) aims to develop novel methods for

surface modification and investigation of cell-

particles interaction for superparamagnetic

nanoparticles. The project further involves

researchers from EPFL (Prof. J. Hubbell,

Dr. A. Petri-Fink) and CSEM (Dr. H. Knapp).

Nanosized superparamagnetic iron oxide

particles (SPIONs) will be coated with bio-

logical molecules and classified regarding

their physical and chemical properties using

a novel technique based on microfluidics.

The particles should help evaluate the

uptake mechanisms used by cells from the

membrane toward the nucleus.

Superparamagnetic nanoparticles were

functionalised for molecular imaging and

for protein separation inside living cells.

Colloidal stability of dispersions of particles

exhibiting different polymer coatings was

evaluated with regard to cellular uptake by

HeLa cells. Already minor modifications of

the nanoparticles surface lead to an altered

stability, uptake, and toxicity. The optimal

cell culture medium should therefore be

individually determined depending on the

particle surface modification. The pathway

of nanoparticles functionalised with organelle-

targeting peptides was identified from the

living cell membrane towards the nucleus.

A first microfluidics device prototype enabling

continuous multi-step functionalisation of

particles has been tested. It is currently

adapted to submicron and micron-sized

particles but work is in progress for develo-

ping a device suitable for continuous func-

tionnalisation of nanosized particles. The

development of a device suited to classifi-

cation of particles regarding their physical

and chemical properties is also underway.

Demand for novel therapeutic or immuno-

genic functional groups or molecules

designed for low molecular weight and

biomacromolecular pharmaceuticals is

increasing. They should act as delivery

systems capable of protecting, transporting,

and selectively depositing those therapeutic

agents at their sites of action. In the field of

magnetic resonance imaging multifunctional

particles are needed in the future. They will

need to fulfil several requirements : chemical

stability under physiological conditions and

sufficient circulation time in vivo; low level of

non-specific protein adsorption from blood

plasma to prevent fast clearance from the

blood stream; presentation of functional bio-

ligands in order to actively target specific

cells and tissue. Of particular interest is the

combination of imaging with the targeted

delivery of therapeutic agents, thus increasing

the safety and efficiency of medical treat-

ment protocols. Such approaches are still

at the research stage, but show high po-

tential for major breakthroughs in medicine.

Examples include the development of com-

posite particles that contain both drug and

contrast agents and allow for site-specific

release of therapeutics upon activation.

The development of a platform for the repro-

ducible, multifunctional, and flexible surface

derivatisation of nanoparticles suitable to

investigate cell-nanoparticle interactions in

living systems and biochemical interaction

is another long-term goal of this thematic

area. This platform should enable (a) the

reproducible and straightforward surface

derivatisation of magnetic particles, (b) the

creation of a particle library, (c) the principal

understanding of the properties of complex

nanoparticles in a physiological environment,

(d) the correlation of material properties to

their biological effects, and (e) the proof of

principle for the identification of the interaction

partners. Both, industry and academia will

gain from the availability of such a device

for systems biology and from the investigation

of cell-nanoparticle interactions. One of the

most important questions for toxicologists

is the quantification of nanoparticles that

have been taken up by cells or organisms.

This question has not been answered today.

Sophisticated applications of superpara-

magnetic particles will be tacked in a further

step. They include magnetic enhanced trans-

fection, treatment of tumours by hyperthermia,

targeted drug delivery and target fishing for

solving problems related to systems biology.

Ph.D. student Sai Reddy of EPFL was awarded the “KPMG Tomorrow’s Market Award” 2007 (Project “Immunofunc-tional Nanoparticles”).

Flow-through particle processor for high yield and high quality functionalisation of particles (EPFL & CSEM).

Nucleus targeting by functionalised superparamagnetic iron oxide nanoparticles (EPFL & CSEM).

hree projects are currently underway

in this thematic area. The first project

deals with tissue replacement materials

consisting of sheets of autologous cells and

biodegradable polymer films. Researchers

from ETH Zurich (Prof. J. Vörös), EPFL

(Prof. J. A. Hubbell), and University Hospital

Zurich (PD Dr. A. Zisch and Prof. F. Weber)

have teamed up to establish a platform for

cell sheet engineering. Cells are organised in

a well-defined, multilayered 3D environment

of designed polymer substrates presenting

specific -and variable- cues for cell growth.

The approach will be validated in vitro and

in vivo. The mechanism of electrochemical

peeling of cell-sheets has been explored

and optimised for different cell types. Poly-

electrolyte carrier films have been developed

that meet specific requirements for creation

of sheets of human multipotent mesenchymal

stromal cells. The methodology of using thin

fibrin-like polyethylene glycol hydrogels has

been established along with the functionalisa-

tion of these hydrogel films with cell-adhesive

peptides. Moreover, a new method for the

bottom-up design of hydrogels has been

invented allowing the production of micro-

patterned thin film hydrogels promoting

cell adhesion only at predefined locations.

Dr. S. Tosatti of ETH Zurich leads a project

aiming to develop a novel class of nano-

structured and biofunctionalised materials

to be primarily used as implants in cardio-

vascular interventions. The materials should

be completely bioresorbable after a period

of around 3-6 months. The research partners

comprise several teams from ETH Zurich

(Prof. N. D. Spencer, Prof. J. F. Löffler, Prof.

P. Uggowitzer and Dr. I. Gerber) and from

Empa (Dr. P. Schmutz) as well as the company

Biotronik AG. The newly developed bio-

resorbable magnesium-based alloy shows

exceptional plasticity together with slow and

homogeneous degradation in simulated body

fluid. The degradation mechanism differs in

artificial plasma compared to simulated

body fluid. In vitro cytotoxicity testing of

the new magnesium alloy WZ21 reveals

that hydrogen gas is a critical parameter

influencing interfacial cell growth.

The third project in this thematic area deals

with photochemically functionalisable scaf-

folds for tissue engineering and drug screen-

ing. The research team involving CSEM (Dr.

C. Hinderling & Dr. M. Liley), ETH Zurich (PD

Dr. H. Hall-Bozic & Prof. P. Seeberger) and

Arrayon Biotechnology SA aims to generate

a novel nanofibrous material. It will be

used as three dimensional scaffolds for

the directed growth of cells, e. g. in nerve

regeneration and nerve guiding. The mate-

rial is shaped as a non-woven mat of nano-

fibers produced by electrospinning.

Proof of feasibility and optimisation of the

electrospinning process for the polysaccha-

ride-based photolinker polymer OptoDex

have been shown. The creation of aligned

fibres and adaptation of the photolinking

protocol is underway. Necessary guidance

cues were successfully produced recom-

binantly and neuronal guidance cues were

covalently attached to polyethylene glycol

and poly(L-lysine) linkers to improve the im-

mobilisation efficiency on OptoDex surfaces.

Using this strategy two different neuronal

cues were attached to Optodex : their pre-

sence was found to increase the viability of

neurones on the coated surfaces.

Although medical device technology perme-

ates numerous areas including orthopaedics,

dental implants, minimally-invasive surgical

devices, cardiovascular surgery, wound

healing applications and diagnostic devices,

this field still suffers from many interfacial

problems such as blood coagulation,

infection, complement activation, foreign

body reactions, and aseptic loosening. In

response, surface modifications were explored

to improve these devices with limited success.

This approach still holds promise in many

device markets but is not a «one-size-fits-all»

solution. The future points to combination

devices, i.e. drug releasing components on

board functional prosthetic implants, as an

emerging clinical technology to improve

performance of implant devices in several

classes. Infection and sustained inflamma-

tory responses are processes that often

severely reduce the success rate of implan-

tations and are the cause of very substantial

health care costs. New antimicrobial and

anti-inflammatory agents have recently

shown promising effects but their effective

combination with implants and surfaces

requires further development and testing

under clinically relevant conditions. New

combination devices are most prominent.

They consist of current orthopaedic and

cardiovascular implants with new added

capabilities on-board or directly associated

drug delivery systems.

Prof. Y. Akiyama (right) and O. Guillaume-Gentil at Tokyo’s Women Medical University.

Electronically controlled cell sheet recovery : a confluent monolayer of fibroblasts grown on a polyelectrolyte coating (left) is detached once the substrate is subjected to an external potential (middle), allowing for the recovery of an intact cell sheet (right). Bar is 1 cm (ETH Zurich, EPFL & University Hospital Zurich).

Bioresorbable stent made of magnesium alloy (© Biotronik) (ETH Zurich & Empa).

Model neuron system for studying onset of myelination. Three murine Schwann cells expressing fluorescently taggednucleus (blue), myelin basic protein (red) and actin cytoskeleton (green) are cultured on poly(L-lysine) adsorbed poly(lactic-co-glycolic acid) fibers (white cylinders) for 20 days (CSEM & ETH Zurich).

20 µm

hree projects are currently underway

in this thematic area. The first project

deals with tissue replacement materials

consisting of sheets of autologous cells and

biodegradable polymer films. Researchers

from ETH Zurich (Prof. J. Vörös), EPFL

(Prof. J. A. Hubbell), and University Hospital

Zurich (PD Dr. A. Zisch and Prof. F. Weber)

have teamed up to establish a platform for

cell sheet engineering. Cells are organised in

a well-defined, multilayered 3D environment

of designed polymer substrates presenting

specific -and variable- cues for cell growth.

The approach will be validated in vitro and

in vivo. The mechanism of electrochemical

peeling of cell-sheets has been explored

and optimised for different cell types. Poly-

electrolyte carrier films have been developed

that meet specific requirements for creation

of sheets of human multipotent mesenchymal

stromal cells. The methodology of using thin

fibrin-like polyethylene glycol hydrogels has

been established along with the functionalisa-

tion of these hydrogel films with cell-adhesive

peptides. Moreover, a new method for the

bottom-up design of hydrogels has been

invented allowing the production of micro-

patterned thin film hydrogels promoting

cell adhesion only at predefined locations.

Dr. S. Tosatti of ETH Zurich leads a project

aiming to develop a novel class of nano-

structured and biofunctionalised materials

to be primarily used as implants in cardio-

vascular interventions. The materials should

be completely bioresorbable after a period

of around 3-6 months. The research partners

comprise several teams from ETH Zurich

(Prof. N. D. Spencer, Prof. J. F. Löffler, Prof.

P. Uggowitzer and Dr. I. Gerber) and from

Empa (Dr. P. Schmutz) as well as the company

Biotronik AG. The newly developed bio-

resorbable magnesium-based alloy shows

exceptional plasticity together with slow and

homogeneous degradation in simulated body

fluid. The degradation mechanism differs in

artificial plasma compared to simulated

body fluid. In vitro cytotoxicity testing of

the new magnesium alloy WZ21 reveals

that hydrogen gas is a critical parameter

influencing interfacial cell growth.

The third project in this thematic area deals

with photochemically functionalisable scaf-

folds for tissue engineering and drug screen-

ing. The research team involving CSEM (Dr.

C. Hinderling & Dr. M. Liley), ETH Zurich (PD

Dr. H. Hall-Bozic & Prof. P. Seeberger) and

Arrayon Biotechnology SA aims to generate

a novel nanofibrous material. It will be

used as three dimensional scaffolds for

the directed growth of cells, e. g. in nerve

regeneration and nerve guiding. The mate-

rial is shaped as a non-woven mat of nano-

fibers produced by electrospinning.

Proof of feasibility and optimisation of the

electrospinning process for the polysaccha-

ride-based photolinker polymer OptoDex

have been shown. The creation of aligned

fibres and adaptation of the photolinking

protocol is underway. Necessary guidance

cues were successfully produced recom-

binantly and neuronal guidance cues were

covalently attached to polyethylene glycol

and poly(L-lysine) linkers to improve the im-

mobilisation efficiency on OptoDex surfaces.

Using this strategy two different neuronal

cues were attached to Optodex : their pre-

sence was found to increase the viability of

neurones on the coated surfaces.

Although medical device technology perme-

ates numerous areas including orthopaedics,

dental implants, minimally-invasive surgical

devices, cardiovascular surgery, wound

healing applications and diagnostic devices,

this field still suffers from many interfacial

problems such as blood coagulation,

infection, complement activation, foreign

body reactions, and aseptic loosening. In

response, surface modifications were explored

to improve these devices with limited success.

This approach still holds promise in many

device markets but is not a «one-size-fits-all»

solution. The future points to combination

devices, i.e. drug releasing components on

board functional prosthetic implants, as an

emerging clinical technology to improve

performance of implant devices in several

classes. Infection and sustained inflamma-

tory responses are processes that often

severely reduce the success rate of implan-

tations and are the cause of very substantial

health care costs. New antimicrobial and

anti-inflammatory agents have recently

shown promising effects but their effective

combination with implants and surfaces

requires further development and testing

under clinically relevant conditions. New

combination devices are most prominent.

They consist of current orthopaedic and

cardiovascular implants with new added

capabilities on-board or directly associated

drug delivery systems.

Prof. Y. Akiyama (right) and O. Guillaume-Gentil at Tokyo’s Women Medical University.

Electronically controlled cell sheet recovery : a confluent monolayer of fibroblasts grown on a polyelectrolyte coating (left) is detached once the substrate is subjected to an external potential (middle), allowing for the recovery of an intact cell sheet (right). Bar is 1 cm (ETH Zurich, EPFL & University Hospital Zurich).

Bioresorbable stent made of magnesium alloy (© Biotronik) (ETH Zurich & Empa).

Model neuron system for studying onset of myelination. Three murine Schwann cells expressing fluorescently taggednucleus (blue), myelin basic protein (red) and actin cytoskeleton (green) are cultured on poly(L-lysine) adsorbed poly(lactic-co-glycolic acid) fibers (white cylinders) for 20 days (CSEM & ETH Zurich).

20 µm

rof. H. Vogel of EPFL leads a project

aiming to develop a versatile platform

for screening membrane-protein-

mediated cellular signalling pathways. The

platform will allow for probing the function

of membrane proteins by simultaneous

electrical and fluorescence measurements.

It will consist of arrays of nanopores machi-

ned into silicon-chips. Each chip will be

individually addressable via micro-fluidic

channels and via electrodes. The project

partners are located at ETH Zurich (Dr. E.

Reimhult & Prof. M. Textor), at CSEM Neu-

châtel (Dr. H. Heinzelmann & Dr. C. Santschi)

and in Lausanne (Ayanda Biosystems SA).

The process enabling the fabrication of

silicon chips comprising arrays and single

nanopores using focused ion beam (FIB)

technique was set-up. The formation of

supported lipid bilayers on nanopore pat-

terned substrates was demonstrated while

the formation mechanism of supported

lipid bilayers for complex and shell-protected

liposomes has been explored. Finally

poly(L-lysine)-graft-poly(ethylene glycol)

selective functionalisation was demonstrated

in view of directed liposome adsorption on

nano- and microscale topographically

structured samples.

Another project intends to prepare immobi-

lised lectins and carbohydrate multivalent

assemblies on surfaces using a compre-

hensive combinatorial approach. The qua-

lity and efficiency of glycosylated target

binding to the protein receptors will be

tested through quantitative and kinetic data.

The project involves researchers from ETH

Zurich (Prof. P. Seeberger and Dr. G. Coul-

lerez) and Arrayon Biotechnology SA in

Neuchâtel. Three terminal sugars of the

human chorionic gonadotropin (hCG)

protein were synthesised in a good yield

and conjugated with a high quantum yield

fluorescent marker.

Prof. V. Vogel of ETH Zurich leads the third

project of this thematic area. Its ambition

is to develop a platform technology where

single cells can be studied in engineered

quasi three-dimensional microwells.

Partners from ETH Zurich (Dr. M. Grandin,

Prof. M. Textor & Dr. M. Smith), Empa

St. Gallen (Dr. K. Maniura), AO Davos and

partners from the pharmaceutical industry

are involved. The physical aspects of the

cellular environments will be further tuned

to learn how cell shape and rigidity of

the microwell walls differentially regulate

diverse cell functions. In addition, the

relationship between the efficiency of

drugs and the state of single cells will

be determined.

The fabrication of highly reproducible

polydimethylsiloxane microwell platforms

has been optimised. Endothelial cells could

be stably entrapped within microwells and

the cells were viable for several days

although cell death was increased in very

constrained microwells. The structural

organisation of the cytoskeleton was

studied as a function of the microwell size

and of the ability of cells to assemble

fibronectin matrix. Moreover immunohisto-

chemical studies confirmed that bone

progenitor cells undergo the process of

osteogenesis in microwells. Promoter-

based reporter constructs to be used as

osteo-specific markers have been success-

fully cloned into constructs in which the

expression of the green fluorescent protein

(GFP) is now bone development-dependent.

A novel platform is being developed for

fabrication of protein arrays by applying a

polyhydroxyalkanoates - extracellular PHA

depolymerase system. Dr. Q. Ren of Empa

coordinates this project. She collaborates

with colleagues of PSI (Dr. H. Schift),

ETH Zurich (Dr. H.-M. Fischer), Empa (Mr.

M. Halbeisen), and with PreenTec AG of

Fribourg. The biopolymer polyhydroxyal-

kanoates (PHA) and the extracellular PHA

depolymerase (ePhaZ) are explored respecti-

vely for protein immobilisation and as a

capture ligand for selective immobilisation.

Different types of PHA were prepared from

Pseudomonas putida GPo1 cells cultivated

in bioreactors with different carbon sources.

Spin-coating followed by UV initiation to

cross-link PHA proves to be the best method

for manufacturing PHA films, whereas oil-

in-water emulsions provide PHA microbeads

of the finest quality. The generation of ePhaZ-

fusion proteins has been achieved and the

study of the interaction between PHA films/

microbeads and ePhaZ is currently underway.

Anne-Kathrin Born and Robert Mathys Jr (managing director of the Foundation).

The «Biochemical Nanofactory» project led

by Prof. René Salathé of EPFL combines

the individual competencies of the four other

participating laboratories (Prof. H. Vogel,

Prof. Y. Barrandon and Dr. J.-M. Fournier

(EPFL) and Dr. H. Knapp (CSEM)) in laser

trapping, micro-fluidics and macro/micro

interfacing, as well as bio-analytics and

smart functionalised surfaces for realising

a micro-fluidic demonstrator system,

compatible with a light microscope. It

comprises several input and output ports

for single cell/vesicle analysis within arrays

created by multiple laser traps.

Laser tweezers offer the unique opportunity

to maintain cells and native vesicles free

from interactions with any substrate. The

team has recently developed a novel concept

for laser trapping in micro-fluidics based

on micro-mirror arrays and demonstrated

multi-array trapping of individual cells, cell

fragments & vesicles in micro-fluidics. They

have also demonstrated that individual cells,

cell fragments & vesicles can be manipu-

lated in microfluidics and addressed by

chemicals thereby activating receptor-mediated

cellular signaling reactions which was

observed on-line in individual objects. The

long-term objective of this project consists in

building up the expertise for establishing a

low-cost technology and platform allowing

ultimate downscaling of chemical and

biotechnological analysis (and production)

for research and industrial applications.

Materials engineering for medical and

diagnostic (microsensor and microarray)

technologies faces a number of exciting

challenges. While many materials exist to

support cells and biosensing applications,

they are often not optimised to allow for

sophisticated screening applications, or

to better support the vitality of cells or are

unsatisfactory when it comes to long term

performance as biomaterials, drug delivery

systems or as devices with integrated

sensory elements. For example, although

deoxyribonucleic acid/ribonucleic acid

(DNA/RNA) sensors are routinely used

today, arrays of proteins and entire

signalling complexes require much more

sophisticated surface engineering and

immobilisation strategies to preserve their

biological activity. New technologies are

thus being developed through the CCMX

MatLife programme that will enable the

presentation of large numbers of nucleic

acids, peptides, proteins, carbohydrates as

well as cells in novel ways. Applications

include rapid and highly parallel read-out

systems concerning gene expression or

protein function. Protein, carbohydrate and

cell-arrayed chips are expected to become

future key elements in drug discovery/

screening and in medical diagnostics.

Integrative engineering approaches that

combine enabling technologies (either

existing or to be developed) and functional

design to produce devices including improved

performance, reliability, ease of handling

and cost-effectiveness will drive future mar-

kets. Examples include biosensor systems

for analysing proteins and protein-carbohy-

drate interactions, cell-based sensor plat-

forms with cells in defined microenviron-

ments and label-free sensing based on

chip-based membrane proteins. Future

success heavily relies on the ability to

combine biological surface modification,

quantitative sensing of biomolecules, micro/

nanofluidics for efficient handling of solutions

and intelligent integration within dependable

devices.

Live image of endothelial cells expressing fluorescently tagged actin skeleton (green) and nucleus (blue) in Micro-wells arrays (ETH Zurich, Empa, AO Davos and industry partners).

rof. H. Vogel of EPFL leads a project

aiming to develop a versatile platform

for screening membrane-protein-

mediated cellular signalling pathways. The

platform will allow for probing the function

of membrane proteins by simultaneous

electrical and fluorescence measurements.

It will consist of arrays of nanopores machi-

ned into silicon-chips. Each chip will be

individually addressable via micro-fluidic

channels and via electrodes. The project

partners are located at ETH Zurich (Dr. E.

Reimhult & Prof. M. Textor), at CSEM Neu-

châtel (Dr. H. Heinzelmann & Dr. C. Santschi)

and in Lausanne (Ayanda Biosystems SA).

The process enabling the fabrication of

silicon chips comprising arrays and single

nanopores using focused ion beam (FIB)

technique was set-up. The formation of

supported lipid bilayers on nanopore pat-

terned substrates was demonstrated while

the formation mechanism of supported

lipid bilayers for complex and shell-protected

liposomes has been explored. Finally

poly(L-lysine)-graft-poly(ethylene glycol)

selective functionalisation was demonstrated

in view of directed liposome adsorption on

nano- and microscale topographically

structured samples.

Another project intends to prepare immobi-

lised lectins and carbohydrate multivalent

assemblies on surfaces using a compre-

hensive combinatorial approach. The qua-

lity and efficiency of glycosylated target

binding to the protein receptors will be

tested through quantitative and kinetic data.

The project involves researchers from ETH

Zurich (Prof. P. Seeberger and Dr. G. Coul-

lerez) and Arrayon Biotechnology SA in

Neuchâtel. Three terminal sugars of the

human chorionic gonadotropin (hCG)

protein were synthesised in a good yield

and conjugated with a high quantum yield

fluorescent marker.

Prof. V. Vogel of ETH Zurich leads the third

project of this thematic area. Its ambition

is to develop a platform technology where

single cells can be studied in engineered

quasi three-dimensional microwells.

Partners from ETH Zurich (Dr. M. Grandin,

Prof. M. Textor & Dr. M. Smith), Empa

St. Gallen (Dr. K. Maniura), AO Davos and

partners from the pharmaceutical industry

are involved. The physical aspects of the

cellular environments will be further tuned

to learn how cell shape and rigidity of

the microwell walls differentially regulate

diverse cell functions. In addition, the

relationship between the efficiency of

drugs and the state of single cells will

be determined.

The fabrication of highly reproducible

polydimethylsiloxane microwell platforms

has been optimised. Endothelial cells could

be stably entrapped within microwells and

the cells were viable for several days

although cell death was increased in very

constrained microwells. The structural

organisation of the cytoskeleton was

studied as a function of the microwell size

and of the ability of cells to assemble

fibronectin matrix. Moreover immunohisto-

chemical studies confirmed that bone

progenitor cells undergo the process of

osteogenesis in microwells. Promoter-

based reporter constructs to be used as

osteo-specific markers have been success-

fully cloned into constructs in which the

expression of the green fluorescent protein

(GFP) is now bone development-dependent.

A novel platform is being developed for

fabrication of protein arrays by applying a

polyhydroxyalkanoates - extracellular PHA

depolymerase system. Dr. Q. Ren of Empa

coordinates this project. She collaborates

with colleagues of PSI (Dr. H. Schift),

ETH Zurich (Dr. H.-M. Fischer), Empa (Mr.

M. Halbeisen), and with PreenTec AG of

Fribourg. The biopolymer polyhydroxyal-

kanoates (PHA) and the extracellular PHA

depolymerase (ePhaZ) are explored respecti-

vely for protein immobilisation and as a

capture ligand for selective immobilisation.

Different types of PHA were prepared from

Pseudomonas putida GPo1 cells cultivated

in bioreactors with different carbon sources.

Spin-coating followed by UV initiation to

cross-link PHA proves to be the best method

for manufacturing PHA films, whereas oil-

in-water emulsions provide PHA microbeads

of the finest quality. The generation of ePhaZ-

fusion proteins has been achieved and the

study of the interaction between PHA films/

microbeads and ePhaZ is currently underway.

Anne-Kathrin Born and Robert Mathys Jr (managing director of the Foundation).

The «Biochemical Nanofactory» project led

by Prof. René Salathé of EPFL combines

the individual competencies of the four other

participating laboratories (Prof. H. Vogel,

Prof. Y. Barrandon and Dr. J.-M. Fournier

(EPFL) and Dr. H. Knapp (CSEM)) in laser

trapping, micro-fluidics and macro/micro

interfacing, as well as bio-analytics and

smart functionalised surfaces for realising

a micro-fluidic demonstrator system,

compatible with a light microscope. It

comprises several input and output ports

for single cell/vesicle analysis within arrays

created by multiple laser traps.

Laser tweezers offer the unique opportunity

to maintain cells and native vesicles free

from interactions with any substrate. The

team has recently developed a novel concept

for laser trapping in micro-fluidics based

on micro-mirror arrays and demonstrated

multi-array trapping of individual cells, cell

fragments & vesicles in micro-fluidics. They

have also demonstrated that individual cells,

cell fragments & vesicles can be manipu-

lated in microfluidics and addressed by

chemicals thereby activating receptor-mediated

cellular signaling reactions which was

observed on-line in individual objects. The

long-term objective of this project consists in

building up the expertise for establishing a

low-cost technology and platform allowing

ultimate downscaling of chemical and

biotechnological analysis (and production)

for research and industrial applications.

Materials engineering for medical and

diagnostic (microsensor and microarray)

technologies faces a number of exciting

challenges. While many materials exist to

support cells and biosensing applications,

they are often not optimised to allow for

sophisticated screening applications, or

to better support the vitality of cells or are

unsatisfactory when it comes to long term

performance as biomaterials, drug delivery

systems or as devices with integrated

sensory elements. For example, although

deoxyribonucleic acid/ribonucleic acid

(DNA/RNA) sensors are routinely used

today, arrays of proteins and entire

signalling complexes require much more

sophisticated surface engineering and

immobilisation strategies to preserve their

biological activity. New technologies are

thus being developed through the CCMX

MatLife programme that will enable the

presentation of large numbers of nucleic

acids, peptides, proteins, carbohydrates as

well as cells in novel ways. Applications

include rapid and highly parallel read-out

systems concerning gene expression or

protein function. Protein, carbohydrate and

cell-arrayed chips are expected to become

future key elements in drug discovery/

screening and in medical diagnostics.

Integrative engineering approaches that

combine enabling technologies (either

existing or to be developed) and functional

design to produce devices including improved

performance, reliability, ease of handling

and cost-effectiveness will drive future mar-

kets. Examples include biosensor systems

for analysing proteins and protein-carbohy-

drate interactions, cell-based sensor plat-

forms with cells in defined microenviron-

ments and label-free sensing based on

chip-based membrane proteins. Future

success heavily relies on the ability to

combine biological surface modification,

quantitative sensing of biomolecules, micro/

nanofluidics for efficient handling of solutions

and intelligent integration within dependable

devices.

Live image of endothelial cells expressing fluorescently tagged actin skeleton (green) and nucleus (blue) in Micro-wells arrays (ETH Zurich, Empa, AO Davos and industry partners).

wo projects are currently running in

this thematic area. Despite the end-

less upwards spiral of modern ultra-

large-scale integration (ULSI) technology,

many experts are predicting a red brick wall

for CMOS by about 2020. Little is known or

practically demonstrated today about how

to design complete circuits and systems

fully benefiting from devices integrated on

nanowires. In this context, the project led

by Prof. Y. Leblebici of EPFL targets the

identification of possible solutions enabling

the continuation of the scaling paradigm.

The project involves groups from EPFL

(Prof. A. Ionescu, Prof. L. Forró, Prof. C.

Piguet, Prof. N. Setter and Dr. D. Atienza),

ETH Zurich (Prof. C. Hierold) and CSEM

(Prof. C. Piguet).

The team has witnessed very promising

developments in the areas of ferro-electric

polymer gate transistors, carbon nanotubes

suspended gate devices and silicon-based

gate-all-around (GAA) field effect transistors.

The concept of a dense crossbar memory/

Programmable Logic Array (PLA) which uses

the new GAA transistors in address encod-

ing was also developed. Test devices have

been successfully manufactured and charac-

terised. Results to be highlighted include

the availability of a process flow for the fa-

brication of suspended single-walled carbon

nanotubes structures and the synthesis

of two kinds of piezoelectric nanowires

(KNbO3 and Pb(Zr,Ti)O3) for sensing and

actuation purposes. The ferroelectricity

retention of monocrystalline Pb(Zr,Ti)O3

nanowires was confirmed for the first time

by temperature variable in situ Transmission

Electron Microscopy. A high quality ferro-

electric gate was integrated on the standard

field-effect transistor (FET) structure and

showed high and stable switching polari-

zation. The tests carried out attest for good

switching properties and long retention

of the spontaneous polarization in the

ferroelectric gate. Finally the fabrication of

long arrays of parallel nanowires was made

possible through a newly developed

technology.

The project coordinated by Prof. J. Vörös of

ETH Zurich and involving researchers from

Prof. R. Spolenak’s group (ETH Zurich) and

Dr. H. Solak’s group (PSI) deals with the

development and the characterisation of

nanowires for applications in (bio-) electronics.

The project targets the creation of large

scale, high-quality nanowire arrays of different

conducting materials in which nanowires

present controlled electronic and mechanical

properties. In another aspect, bio-functio-

nalised nanowires should be applied in bio-

electronics for sensing in microfluidic chan-

nels, and for interfacing neurons with

artificial synapse mimics.

Efforts focussed on establishing the pro-

duction of gold nanowires in large scale

and selecting the suitable techniques for

characterising their performance. A novel

extreme UV interference lithography

scheme enables the production of large

scale gold nanowires with 12 nm line width

– a current world record ! The mechanical

properties of gold nanowires have been

measured on arrays created on polyimide

providing unique insight into the scaling

behaviour of metal nanostructures. Finally

a novel platform allows the creation of self-

assembled gold nanowires based on DNA-

assisted positioning of gold nanoparticles.

Particular emphasis will be placed on :

(i) patterning silicon and other materials to

produce nano-scale devices for computation

and storage, (ii) the design of, and materials

for, integrated micro/nano peripherals that

complement the computational/storage

core of systems and provide the interface

to its environment. In both cases, focus will

be on the properties and processes of the

materials to produce computational and

sensing devices. The need to create new

materials for interfacing the computational

nano-environment to both traditional micro-

systems and the environment will be empha-

sized. These technologies will be key to pro-

ducing effective embedded systems that will

become ubiquitously present. At the same

time, it is becoming mandatory that such

embedded systems be reliable and robust.

On the one hand systems are given control

of critical functions (vehicular control, medical

control). On the other hand we are confronted

with both the downscaling of silicon techno-

logies (beyond the 45 nm node) and the

perspective of using new nano-devices that

have intrinsically higher failure rates. Research

must address the combination of new device-

level error-prone technologies within systems

that must deliver to the user a high level

of dependability. The new techniques have

to be compatible with existing constraints

for system integration, such as low energy

consumption, which were not present in

the design of large fault-tolerant systems

of the past.

Nanodot structures and nanolines (after gold enhancement) created with the Extreme UV inter-ference lithography and the molecular assembly patterning by lift-off processes (ETH Zurich & PSI).

HRTEM image of the interface between [001] SrTiO3 and substrate and KNbO3 nanowires (EPFL, ETH Zurich & CSEM).

(100) or(011)

SrTiO3

wo projects are currently running in

this thematic area. Despite the end-

less upwards spiral of modern ultra-

large-scale integration (ULSI) technology,

many experts are predicting a red brick wall

for CMOS by about 2020. Little is known or

practically demonstrated today about how

to design complete circuits and systems

fully benefiting from devices integrated on

nanowires. In this context, the project led

by Prof. Y. Leblebici of EPFL targets the

identification of possible solutions enabling

the continuation of the scaling paradigm.

The project involves groups from EPFL

(Prof. A. Ionescu, Prof. L. Forró, Prof. C.

Piguet, Prof. N. Setter and Dr. D. Atienza),

ETH Zurich (Prof. C. Hierold) and CSEM

(Prof. C. Piguet).

The team has witnessed very promising

developments in the areas of ferro-electric

polymer gate transistors, carbon nanotubes

suspended gate devices and silicon-based

gate-all-around (GAA) field effect transistors.

The concept of a dense crossbar memory/

Programmable Logic Array (PLA) which uses

the new GAA transistors in address encod-

ing was also developed. Test devices have

been successfully manufactured and charac-

terised. Results to be highlighted include

the availability of a process flow for the fa-

brication of suspended single-walled carbon

nanotubes structures and the synthesis

of two kinds of piezoelectric nanowires

(KNbO3 and Pb(Zr,Ti)O3) for sensing and

actuation purposes. The ferroelectricity

retention of monocrystalline Pb(Zr,Ti)O3

nanowires was confirmed for the first time

by temperature variable in situ Transmission

Electron Microscopy. A high quality ferro-

electric gate was integrated on the standard

field-effect transistor (FET) structure and

showed high and stable switching polari-

zation. The tests carried out attest for good

switching properties and long retention

of the spontaneous polarization in the

ferroelectric gate. Finally the fabrication of

long arrays of parallel nanowires was made

possible through a newly developed

technology.

The project coordinated by Prof. J. Vörös of

ETH Zurich and involving researchers from

Prof. R. Spolenak’s group (ETH Zurich) and

Dr. H. Solak’s group (PSI) deals with the

development and the characterisation of

nanowires for applications in (bio-) electronics.

The project targets the creation of large

scale, high-quality nanowire arrays of different

conducting materials in which nanowires

present controlled electronic and mechanical

properties. In another aspect, bio-functio-

nalised nanowires should be applied in bio-

electronics for sensing in microfluidic chan-

nels, and for interfacing neurons with

artificial synapse mimics.

Efforts focussed on establishing the pro-

duction of gold nanowires in large scale

and selecting the suitable techniques for

characterising their performance. A novel

extreme UV interference lithography

scheme enables the production of large

scale gold nanowires with 12 nm line width

– a current world record ! The mechanical

properties of gold nanowires have been

measured on arrays created on polyimide

providing unique insight into the scaling

behaviour of metal nanostructures. Finally

a novel platform allows the creation of self-

assembled gold nanowires based on DNA-

assisted positioning of gold nanoparticles.

Particular emphasis will be placed on :

(i) patterning silicon and other materials to

produce nano-scale devices for computation

and storage, (ii) the design of, and materials

for, integrated micro/nano peripherals that

complement the computational/storage

core of systems and provide the interface

to its environment. In both cases, focus will

be on the properties and processes of the

materials to produce computational and

sensing devices. The need to create new

materials for interfacing the computational

nano-environment to both traditional micro-

systems and the environment will be empha-

sized. These technologies will be key to pro-

ducing effective embedded systems that will

become ubiquitously present. At the same

time, it is becoming mandatory that such

embedded systems be reliable and robust.

On the one hand systems are given control

of critical functions (vehicular control, medical

control). On the other hand we are confronted

with both the downscaling of silicon techno-

logies (beyond the 45 nm node) and the

perspective of using new nano-devices that

have intrinsically higher failure rates. Research

must address the combination of new device-

level error-prone technologies within systems

that must deliver to the user a high level

of dependability. The new techniques have

to be compatible with existing constraints

for system integration, such as low energy

consumption, which were not present in

the design of large fault-tolerant systems

of the past.

Nanodot structures and nanolines (after gold enhancement) created with the Extreme UV inter-ference lithography and the molecular assembly patterning by lift-off processes (ETH Zurich & PSI).

HRTEM image of the interface between [001] SrTiO3 and substrate and KNbO3 nanowires (EPFL, ETH Zurich & CSEM).

(100) or(011)

SrTiO3

he project «Lab-on-a-Chip for analysis

and diagnostics» led by Prof. M. Gijs

of EPFL and involving other research

groups from EPFL (Prof. E. Charbon, Prof.

Y. Leblebici, Prof. P. Muralt, Prof. H.-A. Klok,

Dr. F. K. Gürkaynak, Dr. Y. Leterrier), CSEM

(Dr. G. Voirin) and the company Microsens,

aims to develop lab-on-a-chip devices suited

for the detection of malaria, the detection of

antibiotics in milk and the detection of pH

and ionic strength in environmental water.

A complementary metal-oxide-semiconduc-

tor (CMOS) system enabling manipulation

of magnetic microparticles through a

magnetic field and in situ optical detection

has been realised. Those microparticles

have been grafted with polymer brushes

with plasmodium lactate dehydrogenase

(pLDH) antibodies for detection of the

malaria virus. A magnetic transportation

system for micro- and nanoparticles with

integrated optical detection was also

realised on a CMOS chip. Regarding the

detection of antibiotics in milk, ppb-level

optical detection has been demonstrated.

Individual assays have been carried out on

the wavelength interrogated optical system

(WIOS) chip for various antibiotic families.

One axis of the MERU proposal is the

development of new alloys and processing

routes for various applications and the

improvement of characterising techniques.

Alloy development for structural or func-

tional applications relies on the possibility

of making combinatory experiments in a

fast and efficient way. One way is to pro-

duce materials with composition gradients

with testing made afterwards at a very local

scale, e.g., nano-indentation for mechanical

properties or local optical or electrical mea-

surements for functions. This raises then the

question of up-scaling properties measured

at a very local scale to those of more bulk

materials, bringing sometimes fundamental

questions when the characteristic length

scales associated with the phenomena

involved become comparable to that of the

specimen or of the measurement technique.

New production or assemblage processes

are also required for metallic alloys. For

example, new metallic materials such as bulk

metallic glasses (BMG) and metallic foams,

metal matrix composites (MMC) offer new

and quite unique mechanical properties.

A multidetection assay has been success-

fully achieved for simultaneous detection

of fluoroquinolone and sulfonamide. Test

measurements «in the field» have been

carried out in Nestlé lab facilities, comparing

WIOS detection vs. conventional techniques.

In the sub-project dedicated to environmental

monitoring, a shear-mode acousto-gravimetric

resonator based on aluminum nitride thin

films and polymer brushes was succesfully

processed on top of an acoustic reflector

structure. The chemical or biological cou-

pling to the water is mediated by a polymer

brush layer that immobilises and accumu-

lates the species to be measured, giving

rise to a change in the oscillator frequency

of the acoustic structure.

The development of gene and protein

arrays has opened tremendous opportuni-

ties for measuring gene/protein expressions

over repeated experiments. The scope of

applicability of microarrays goes from

medical diagnosis to bio-discovery. In

particular microarray technology is fit to

provide insight into gene regulatory

mechanisms and support for fast diagnosis

(e.g., infectious disease screening).

Laser welding of dissimilar materials is of

great interest for many industries in the

watch or medical sectors, but also in the

automotive and aeronautic sectors. While

the metallurgy of materials A and B are well

known, the assemblage of A and B by metal-

lurgical bonds requires a deep understand-

ing of both thermodynamics and processes.

Finally, novel characterising techniques

such as in situ X-ray radiography or tomo-

graphy, neutron scattering, orientation

imaging using EBSD combined with EDX

chemical analyses methods, nano-testing

devices, etc, allow to characterise accu-

rately and in depth metallic alloys down to

very low scale.

At the same time new alloys are produced

and analysed, computer simulation has

really become an indispensable tool in

metallurgy. For «traditional» metallurgy of

standard composition alloys, the effort of

researchers is directed towards integrated

modelling in order to model, understand,

calculate and optimise processing routes

as a function of the final desired properties.

Although microarrays are already highly

developed and widely used, they are still

far from optimised. With respect to protein

microarrays, for example, important

challenges include the development of

robust and generally applicable methods

for the covalent immobilisation of proteins

with retention of structure and function,

and the design of new substrate materials

that are not sensitive towards non-specific

protein adsorption. In the area of micro-

fluidics, important materials challenges lie

in surface structuring and surface chemis-

try in order to better control and direct fluid

Further research will involve the combina-

tion of hardware design using various

materials technologies as well as software

technologies for processing the measured

data, and will link them to other diagnostic

or ontological information. A variety of

materials should be considered, with parti-

cular reference to their compatibility with

integrated system technology and the living

sample materials to be processed by the

lab-on-a-chip.

Along less traditional ways, multi-scale

modelling requires the development of

dedicated tools which can encompass

nearly 10 orders of magnitude, from the

atomistic to the process scale.

At the scale of a small population of atoms,

ab initio calculations can be used to model

the optical or electrical response of metallic

systems, impurity-defect structures for use

in Kinetic Monte Carlo and free energy

cluster expansion methods. At the scale of

a few million atoms, molecular dynamics

can help in the understanding and calculation

of mechanical properties of nanoparticles,

the structure and property of diffuse solid-

liquid interfaces or the interactions between

metallic systems and radiation. Numerical

simulation methods such as pseudo-front

tracking and phase field methods allow

modelling the formation of microstructures

and defects for multi-component and multi-

phase systems. At a larger scale, granular

approaches or cellular automata can take

information from the microstructure scale

level for the modelling at the scale of a large

population of grains (macrostructures).

Ulrike Lehmann getting her prize in Tokyo.

Lab-on-a-chip for analysis and diagnostics (EPFL & CSEM).

Gold infiltration at austenite grain boundaries during laser welding of gold and steel. (After D. Favez et al., Intergranular penetration of liquid gold at stainless steel grain boundaries, French Soc. Metal., Paris (2008)).

50 µm

very low scale.

lab-on-a-chip.

50 µm

very low scale.

lab-on-a-chip.

50 µm

he «Nano- and Microscale Materials

Characterisation» analytical platform

is directed by Prof. Hans Josef Hug.

Chiara Corticelli is in charge of industrial

liaison. The Management Board comprises

Prof. Cécile Hébert (EPFL), Prof. Bruce Pat-

terson (PSI), Prof. Marcus Textor (ETH Zurich),

and includes the Management Team. An

independent international board of referees

advises the analytical platform for strategic

decisions.

The projets funded through CCMX in this

area are divided into three categories :

• Projects targeting the development of

new analytical tools, methods or instru-

mentation for the analysis of physical,

chemical, or biological properties on the

scale below 100 nm;

• Projects involving the purchase of analy-

tical instrumentation or components to

complete the existing offer of the CCMX

affiliated institutions. Matching funds

from the home-institution should be

provided and further development of the

instrumentation should be envisioned

after such a project, preferably with an

industrial partner;

• Rapid analytical projects using existing

instrumentation for single experiments

with a well-defined duration or multiple

experiments, possibly on different instru-

ments, or to carry on test experiments

for feasibility studies at the nanoscale.

In general, projects bringing a positive

impact on other CCMX ongoing research

activities or that are of interest to several

ETH domain laboratories and/or industry

are preferred. Twelve projects have been

funded in 2007, many of which have already

led to exciting success stories as revealed

in the coming pages.

The project «Development of Self-Sensing

and -Actuating Probe for Dynamic Mode

AFM at Cryogenic Temperature» led by

Prof. N. de Rooij (EPFL) and involving Prof.

K. Ensslin (ETH Zurich) focuses on two

objectives : the development of a new type

of tuning fork probe for the atomic force

microscope (AFM) based on a novel probe

concept invented in a previous project and

the development of an easy interface for

mounting the probe onto an AFM platform.

The developed tuning fork AFM probe

consists of a quartz tuning fork and a

cantilever. The objective of the first year

was reached as a model of this probe was

developed based on two coupled spring-

mass systems. The determining param-

eters are the mass and the spring constant

of the cantilever. The behaviour of the

quartz tuning fork due to the coupling from

the cantilever could therefore be deter-

mined. A shift in the resonance frequency

of the in-phase peak of the tuning fork

occurs as the spring constant of the

cantilever increases. This shift reaches a

saturation state that should be avoided to

achieve reasonable sensitivity in a frequen-

cy modulation scheme. The conducted

experiments show that this model de-

scribes the qualitative behaviour of the

system but further development will be

required to achieve good quantitative

predictions.

A new generation scanning anode field emis-

sion microscope (SAFEM) for the inspection

of field emission properties of planar cold

cathodes is being developed in a project

carried out by Dr. O. Gröning (EMPA). The

instrument will set new standards in the

field of cold cathode characterisation with

regard to spatial resolution (which in most

measurement of planar field emission cathode

is neglected). At this stage the main hardware

design and bulk of the operation software

has been developed and appropriate sup-

pliers have been identified. The core of the

SAFEM - the high precision UHV translation

stages - is being manufactured by MICOS

in Germany and will be delivered in the first

semester of 2008. A key feature of the new

SAFEM will be its userfriendliness making it

possible for external research groups to carry

out routine cold cathode characterisation.

Prof. U. Sennhauser (EMPA) and Prof. C. Hafner

(ETH Zurich) are developing a new «double-

passage» scanning near-field optical micro-

scope (SNOM) that should show higher

resolution than the «single-passage» SNOM

thanks to a novel structuring of the tip

cladding. A scanning probe microscope

(SPM) set-up suitable for various SNOM

configurations has been designed and

built; it will soon be operational. The basic

scanning functionality is effective and will

be optimised. The possibilities to modify

optical fibre SNOM tips with focused ion

beam (FIB) have been investigated and

simple structures on fibre tips have been

produced. As commercial tips are not

suitable, an etching process has already

been set up but the obtained tip shape and

surface quality will be further improved.

A novel type of scanning X-ray microscope

is being developed by Dr. I. Schmid (Empa)

who has teamed up with Dr. J. Raabe and

Dr. C. Quitmann (PSI). This instrument will

combine the chemical specificity of X-ray

absorption spectroscopy with the spatial

resolution (< 5nm) of a scanning force

microscope. This instrument should signi-

ficantly impact nanotechnology, material

science and even industrial applications

(i.e. semiconductor industry).

The conceptual design of the instrument

was achieved already in March while the

fabrication and assembly has been going

on since August 2007.

The five multi-purpose microscopes of the

Swiss Scanning Probe User Laboratory

(SUL) project led by Dr. R. Crockett (Empa)

will be made available to industrial users

Etched fibre tip for the Focused Ion Beam instrument mounted on a Transmission Electron Microscope sample holder (Empa and ETH Zurich).

10 µm

and to academic institutions for service

measurements and for education and

technical training courses. It is a unique

facility in Switzerland. CCMX and Empa are

joining forces to purchase three scanning

force microscopes while another instru-

ment is being constructed by the Empa

Laboratory for Nanoscale Materials Science

and NanoScan AG. This fourth instrument,

a «physical property measurement system»

scanning force microscope (PPMS-SFM), is

expected to be operational by summer 2008.

Dr. B. Hinz (EPFL) investigates cytoskeletal

proteins in living cells using scanning probe

microscopy. These cells generate fibrosis of

liver, heart, kidney and lung in response to

mechanical stress. Targeting their molecular

stress-detectors offers novel strategies to

develop anti-fibrotic therapies. The aim of

the project is to determine how mechanical

forces, exerted on the single molecule level,

control the development and function of

contractile connective tissue cells. With

CCMX support a life science atomic force

microscope (AFM) could be acquired. This

instrument significantly contributed to the

disclosure that fibrogenic cells de novo form

specialised contacts that intercellularly co-

ordinate their destructive contractile activity.

The mechanical stability of these contacts

could be attributed to the high adhesion of

specific transmembrane proteins on the

single molecule level as inhibition of these

proteins reduces contraction of tissue-like

matrix. In a second publication, a novel

mechanism of how fibrogenic cells activate

growth factors from their surrounding

extracellular matrix was described. These

cells use specific cell-matrix receptors to

literally pull on the biologically inactive

growth factor. The mechanical force then

liberates the active cytokine which feeds

back on the cell to maintain its fibrogenic

character. Again, by blocking the specific

matrix receptor the vicious cycle leading to

fibrosis could be interrupted.

Dr. U. Sennhauser and Dr. S Liebert-Winter

of Empa investigate weak mode failures in

semiconductor devices using 3D transmis-

sion electron microscopy together with NXP

Semiconductors Zurich. The TEM analysis

of a sample which had failed during the

electromigration stress test showed seven

kinds of defects : (1) low k dielectric material

with stress reliefs which are not caused by the

TEM imaging, (2) porousity of the tantalum

barrier, (3) migration of copper through the

tantalum barrier down to the copper line

below which caused an electric short, (4)

accumulation of copper and (5) correspond-

ing depletion area, (6) stress relief in the

copper line below the stressed via and (7)

cracks and/ or stress relief in the copper

line above the stressed via. Before now no

information about the thermal stress of

copper lines and the low k dielectric material

around the stressed via was available. Also

the porosity of the tantalum barrier could be

observed for the first time.

The project led by Dr. S. Rast (University of

Basel) in collaboration with Dr. U. Sennhauser

(Empa) aims to shrink the dimension of a

micrometer sized magnetic particle attached

to an ultrasensitive force sensor in order to

achieve highest possible magnetic field

gradient. The dimension of a micrometer

sized hard magnetic tip, glued on a force

sensor with attonewton sensitivity was

shrinked to the nm regime with the focused

ion beam (FIB). The magnetic and dissipa-

tive properties of individual hard magnetic

particles were investigated with cantilever

magnetometry. It turns out that the milling

process with Ga+ ions does not significant-

ly affect the magnetic properties of the tip,

if the pristine tip has already excellent

magnetic properties. The magnetocrystal-

line anisotropy energy and coercitive field of

the nanometer sized particles are in good

agreement with bulk values. Since the mag-

netic properties remain unchanged at small

dimensions, far higher field gradients can

be reached (10 -100 G/nm). The dissipation

of the magnet in the external magnetic field

is comparable to the internal friction of the

ultrasensitive cantilever. These values are

exceeded by non-contact friction at tip

sample separations below 10 nm.

The «AMORTEM» project aims to minimise

the damage induced by focused ion beam

(FIB) irradiation to sensitive materials for

high resolution analysis by transmission

electron microscopy (TEM). A reduction of

the thickness of the amorphous layers on

each side of the TEM lamellae allows for

better quality high resolution TEM micro-

graphs for material analysis. This project is

carried out by Dr. U. Sennhauser (Empa) in

collaboration with Dr. T. Graule (Empa) and

Dr. E. Müller (ETH Zurich). Two methods

were compared to each other and to refe-

rence TEM lamellae. The first method uses

low energy (7 keV instead of the usual 30 keV)

FIB irradiation while the other applies very

low energy (<2 keV) broad ion beam irradia-

tion in a separate machine. Both techniques

enabled lower thickness of the damaged

layers; however the best results were ob-

tained using the broad ion beam milling

machine evaluated and acquired during the

AMORTEM project. Visibility of the crystal-

line structure is improved as showed by

high resolution TEM microscopy.

One key task in the near future is to cata-

logue the analytical ressources available for

characterising materials at the nano- and

microscale within ETH Domain institutions

and subsequently provide a single entry point

to industry. The CCMX analytical platform

will therefore emphasise the coordination

of facilities currently on offer in the partner

institutions. Educational training will be of-

fered in specific areas of micro-/nanoscale

analysis.

New analytical instrumentation will continue

to be developed, with a clear accent on re-

sponding to the needs of CCMX researchers

involved in pre-competitive research projects.

Information exchange with the Education and

Research Units will thus be strenghtened.

Funding of rapid analytical projects will be

expanded. Such projects facilitate inter-

institutional use of analytical equipment

available within the ETH Domain or support

the development of test experiments between

an ETH Domain group and an industrial

partner provided that a sufficient distinction

from conventional service measurements is

documented.

AFM image of the phase morphology of a polythiophene/polystyrene mixture spin-coated from chlorobenzene after removal of polystyrene in hexane (Empa).

Fibrotic cells grown on the force probe cantilever (blue) of an atomic force microscope (AFM) develop contractile fibers (green). Touching AFM- and glass-cultured cells (inset) induces forma-tion of cell-to-cell contacts whose strength is measured with the AFM on the single molecule level (EPFL).

and to academic institutions for service

measurements and for education and

technical training courses. It is a unique

facility in Switzerland. CCMX and Empa are

joining forces to purchase three scanning

force microscopes while another instru-

ment is being constructed by the Empa

Laboratory for Nanoscale Materials Science

and NanoScan AG. This fourth instrument,

a «physical property measurement system»

scanning force microscope (PPMS-SFM), is

expected to be operational by summer 2008.

Dr. B. Hinz (EPFL) investigates cytoskeletal

proteins in living cells using scanning probe

microscopy. These cells generate fibrosis of

liver, heart, kidney and lung in response to

mechanical stress. Targeting their molecular

stress-detectors offers novel strategies to

develop anti-fibrotic therapies. The aim of

the project is to determine how mechanical

forces, exerted on the single molecule level,

control the development and function of

contractile connective tissue cells. With

CCMX support a life science atomic force

microscope (AFM) could be acquired. This

instrument significantly contributed to the

disclosure that fibrogenic cells de novo form

specialised contacts that intercellularly co-

ordinate their destructive contractile activity.

The mechanical stability of these contacts

could be attributed to the high adhesion of

specific transmembrane proteins on the

single molecule level as inhibition of these

proteins reduces contraction of tissue-like

matrix. In a second publication, a novel

mechanism of how fibrogenic cells activate

growth factors from their surrounding

extracellular matrix was described. These

cells use specific cell-matrix receptors to

literally pull on the biologically inactive

growth factor. The mechanical force then

liberates the active cytokine which feeds

back on the cell to maintain its fibrogenic

character. Again, by blocking the specific

matrix receptor the vicious cycle leading to

fibrosis could be interrupted.

Dr. U. Sennhauser and Dr. S Liebert-Winter

of Empa investigate weak mode failures in

semiconductor devices using 3D transmis-

sion electron microscopy together with NXP

Semiconductors Zurich. The TEM analysis

of a sample which had failed during the

electromigration stress test showed seven

kinds of defects : (1) low k dielectric material

with stress reliefs which are not caused by the

TEM imaging, (2) porousity of the tantalum

barrier, (3) migration of copper through the

tantalum barrier down to the copper line

below which caused an electric short, (4)

accumulation of copper and (5) correspond-

ing depletion area, (6) stress relief in the

copper line below the stressed via and (7)

cracks and/ or stress relief in the copper

line above the stressed via. Before now no

information about the thermal stress of

copper lines and the low k dielectric material

around the stressed via was available. Also

the porosity of the tantalum barrier could be

observed for the first time.

The project led by Dr. S. Rast (University of

Basel) in collaboration with Dr. U. Sennhauser

(Empa) aims to shrink the dimension of a

micrometer sized magnetic particle attached

to an ultrasensitive force sensor in order to

achieve highest possible magnetic field

gradient. The dimension of a micrometer

sized hard magnetic tip, glued on a force

sensor with attonewton sensitivity was

shrinked to the nm regime with the focused

ion beam (FIB). The magnetic and dissipa-

tive properties of individual hard magnetic

particles were investigated with cantilever

magnetometry. It turns out that the milling

process with Ga+ ions does not significant-

ly affect the magnetic properties of the tip,

if the pristine tip has already excellent

magnetic properties. The magnetocrystal-

line anisotropy energy and coercitive field of

the nanometer sized particles are in good

agreement with bulk values. Since the mag-

netic properties remain unchanged at small

dimensions, far higher field gradients can

be reached (10 -100 G/nm). The dissipation

of the magnet in the external magnetic field

is comparable to the internal friction of the

ultrasensitive cantilever. These values are

exceeded by non-contact friction at tip

sample separations below 10 nm.

The «AMORTEM» project aims to minimise

the damage induced by focused ion beam

(FIB) irradiation to sensitive materials for

high resolution analysis by transmission

electron microscopy (TEM). A reduction of

the thickness of the amorphous layers on

each side of the TEM lamellae allows for

better quality high resolution TEM micro-

graphs for material analysis. This project is

carried out by Dr. U. Sennhauser (Empa) in

collaboration with Dr. T. Graule (Empa) and

Dr. E. Müller (ETH Zurich). Two methods

were compared to each other and to refe-

rence TEM lamellae. The first method uses

low energy (7 keV instead of the usual 30 keV)

FIB irradiation while the other applies very

low energy (<2 keV) broad ion beam irradia-

tion in a separate machine. Both techniques

enabled lower thickness of the damaged

layers; however the best results were ob-

tained using the broad ion beam milling

machine evaluated and acquired during the

AMORTEM project. Visibility of the crystal-

line structure is improved as showed by

high resolution TEM microscopy.

One key task in the near future is to cata-

logue the analytical ressources available for

characterising materials at the nano- and

microscale within ETH Domain institutions

and subsequently provide a single entry point

to industry. The CCMX analytical platform

will therefore emphasise the coordination

of facilities currently on offer in the partner

institutions. Educational training will be of-

fered in specific areas of micro-/nanoscale

analysis.

New analytical instrumentation will continue

to be developed, with a clear accent on re-

sponding to the needs of CCMX researchers

involved in pre-competitive research projects.

Information exchange with the Education and

Research Units will thus be strenghtened.

Funding of rapid analytical projects will be

expanded. Such projects facilitate inter-

institutional use of analytical equipment

available within the ETH Domain or support

the development of test experiments between

an ETH Domain group and an industrial

partner provided that a sufficient distinction

from conventional service measurements is

documented.

AFM image of the phase morphology of a polythiophene/polystyrene mixture spin-coated from chlorobenzene after removal of polystyrene in hexane (Empa).

Fibrotic cells grown on the force probe cantilever (blue) of an atomic force microscope (AFM) develop contractile fibers (green). Touching AFM- and glass-cultured cells (inset) induces forma-tion of cell-to-cell contacts whose strength is measured with the AFM on the single molecule level (EPFL).

MMNS organised a workshop in relation to

the CCMX funded project entitled «Materials,

Devices and Design Technologies for Nano-

electronic Systems Beyond Ultimately

Scaled CMOS» in July at EPFL. It attracted

60 participants, 90% of whom were from

academia. Five prominent scientists gave

two back-to-back lectures; the first one

was an overview of the subject, while

the second one provided a more detailed

insight. The aim of the workshop was to

present the audience with the possible

implications of emerging nanotechnologies

and the exciting opportunities they may

hold for academia and for the industry.

The MatLife Tutorial Type Workshop on

high-priority areas of materials for the life

sciences such as materials in biosensors,

tissue engineering and carrier systems for

targeted drug delivery was given by leaders

of the field and held in combination with

the BIOSURF VII conference in August. This

workshop was specifically devoted to the

science of functional interfaces directing

biological response. The 128 participants

consisting of engineers, chemists, biologists

and clinicians working on interdisciplinary

approaches originated both from academic

institutions (85%) and industry (15%) from

Switzerland, Europe and overseas.

The first SPERU Annual Course focussing

on the processing and characterisation of

particles and thin films was held over four

days at the end of 2007 in Lucern. The course

was given by experts from Empa, EPFL,

ETH Zurich and CSEM who encouraged

direct interactions with the participants.

37% of the 38 participants originated from

the specialty chemicals, pharmaceuticals,

sensors and watch industries. Constructive

remarks were collected ensuring that the

2008 course can correspond even better to

the audience’s needs.

The pilot phase of a joint EPFL/ETHZ Master

Orientation on Molecular Bioengineering/

Biomaterials was initiated in the 2007-2008

academic year. Student mobility is finan-

ced at the level of the Centre. If successful,

the programme will be reinforced for the

following academic year.

CCMX’s Master Support Programme pro-

vided partial financial support to seven master

students from abroad to support their master

theses within CCMX funded projects, the

programme will continue in 2008.

Following the survey that was carried out

by CCMX on «The demands of the Swiss

industry in materials R&D : challenges and

opportunities» a workshop was organised

in Bern in January to present and discuss

the results and the outcome of the survey.

More than 25 people from industry attended

together with the representatives of CCMX

and its ERUs and platform. The creation of

a new ERU on metallurgy (MERU) was the

direct response to the needs that transpired

from the survey and the workshop. SPERU

organised its own workshop in April in

Olten following discussions that had

initiated at the Bern workshop. The main

topic was to discuss and define SPERU’s

future thematic areas together with 12

participants from industry.

The first Annual Meeting of CCMX took

place in Fribourg in March. This represented

a good opportunity for the 250 participants

from industry and academia to network and

to be introduced to CCMX’s activities. On-

going projects were presented and possi-

bilities for collaboration were discussed.

The first SPERU Technology Aperitif

targeting the watch industry and held in

July in Lausanne attracted more than 30

participants who learnt about the latest

performances of materials of all classes

from a panel of speakers from EPFL, ETH

Zurich and CSEM.

MatLife participated in the European Science

Foundation (ESF-EMBO) Conference on «Bio-

logical Surfaces and Interfaces» that was

held in July in Spain. CCMX was presented

overall and focus was given to MatLife acti-

vities. The conference programme was divi-

ded into 6 sessions with 25 invited speakers.

The BIOSURF VII Conference held in Zurich

in August and organised by MatLife was a

great success with 27 international

speakers from academia and industry, 245

participants from 17 countries and 132

poster presentations.

In September, CCMX presented its activi-

ties on a 24 m2 stand at the NanoEurope

fair in St-Gallen. A total of approximately

3’500 visitors was recorded over the three

days of trade show and conferences.

The MERU Metallurgy Day in September

defined industrial needs in metallurgy R&D

and provided an overview of the competen-

cies and equipment available at institutions

of the ETH Domain and CSEM. Attendance

exceeded expectations, with 25 representa-

tives from Swiss industry.

SPERU Annual Course.

CCMX Annual Meeting (left) and BIOSURF VII Conference (right).

. Al-B

MMNS organised a workshop in relation to

the CCMX funded project entitled «Materials,

Devices and Design Technologies for Nano-

electronic Systems Beyond Ultimately

Scaled CMOS» in July at EPFL. It attracted

60 participants, 90% of whom were from

academia. Five prominent scientists gave

two back-to-back lectures; the first one

was an overview of the subject, while

the second one provided a more detailed

insight. The aim of the workshop was to

present the audience with the possible

implications of emerging nanotechnologies

and the exciting opportunities they may

hold for academia and for the industry.

The MatLife Tutorial Type Workshop on

high-priority areas of materials for the life

sciences such as materials in biosensors,

tissue engineering and carrier systems for

targeted drug delivery was given by leaders

of the field and held in combination with

the BIOSURF VII conference in August. This

workshop was specifically devoted to the

science of functional interfaces directing

biological response. The 128 participants

consisting of engineers, chemists, biologists

and clinicians working on interdisciplinary

approaches originated both from academic

institutions (85%) and industry (15%) from

Switzerland, Europe and overseas.

The first SPERU Annual Course focussing

on the processing and characterisation of

particles and thin films was held over four

days at the end of 2007 in Lucern. The course

was given by experts from Empa, EPFL,

ETH Zurich and CSEM who encouraged

direct interactions with the participants.

37% of the 38 participants originated from

the specialty chemicals, pharmaceuticals,

sensors and watch industries. Constructive

remarks were collected ensuring that the

2008 course can correspond even better to

the audience’s needs.

The pilot phase of a joint EPFL/ETHZ Master

Orientation on Molecular Bioengineering/

Biomaterials was initiated in the 2007-2008

academic year. Student mobility is finan-

ced at the level of the Centre. If successful,

the programme will be reinforced for the

following academic year.

CCMX’s Master Support Programme pro-

vided partial financial support to seven master

students from abroad to support their master

theses within CCMX funded projects, the

programme will continue in 2008.

Following the survey that was carried out

by CCMX on «The demands of the Swiss

industry in materials R&D : challenges and

opportunities» a workshop was organised

in Bern in January to present and discuss

the results and the outcome of the survey.

More than 25 people from industry attended

together with the representatives of CCMX

and its ERUs and platform. The creation of

a new ERU on metallurgy (MERU) was the

direct response to the needs that transpired

from the survey and the workshop. SPERU

organised its own workshop in April in

Olten following discussions that had

initiated at the Bern workshop. The main

topic was to discuss and define SPERU’s

future thematic areas together with 12

participants from industry.

The first Annual Meeting of CCMX took

place in Fribourg in March. This represented

a good opportunity for the 250 participants

from industry and academia to network and

to be introduced to CCMX’s activities. On-

going projects were presented and possi-

bilities for collaboration were discussed.

The first SPERU Technology Aperitif

targeting the watch industry and held in

July in Lausanne attracted more than 30

participants who learnt about the latest

performances of materials of all classes

from a panel of speakers from EPFL, ETH

Zurich and CSEM.

MatLife participated in the European Science

Foundation (ESF-EMBO) Conference on «Bio-

logical Surfaces and Interfaces» that was

held in July in Spain. CCMX was presented

overall and focus was given to MatLife acti-

vities. The conference programme was divi-

ded into 6 sessions with 25 invited speakers.

The BIOSURF VII Conference held in Zurich

in August and organised by MatLife was a

great success with 27 international

speakers from academia and industry, 245

participants from 17 countries and 132

poster presentations.

In September, CCMX presented its activi-

ties on a 24 m2 stand at the NanoEurope

fair in St-Gallen. A total of approximately

3’500 visitors was recorded over the three

days of trade show and conferences.

The MERU Metallurgy Day in September

defined industrial needs in metallurgy R&D

and provided an overview of the competen-

cies and equipment available at institutions

of the ETH Domain and CSEM. Attendance

exceeded expectations, with 25 representa-

tives from Swiss industry.

SPERU Annual Course.

CCMX Annual Meeting (left) and BIOSURF VII Conference (right).

. Al-B

The CCMX steering committee agreed to

continue funding 15 of the current flagship

projects following the requests for continu-

ation and the excellent results that were

shown. These projects will be running into

2008 and 2009.

A new call for proposals was launched

at the end of 2007. 22 outline proposals

were received in October 2007 and 15

full proposals were finally submitted in

January 2008. At the moment of the

writing of this report the projects are

being evaluated and the process will allow

for new projects to be funded as of April

2008. These projects will be funded ac-

cording to the new CCMX rule requiring

matching funds from the industry.

The analytical platform (NMMC) will carry out

a project entitled “Evaluation of the analytical

instrumentation within the ETH Domain”.

The goal of this survey is to establish the

situation of Analytical Instrumentation in

the ETH Domain. It will lead to the creation

of an analytical portal on the CCMX website.

Education activities planned for 2008 in-

clude the SPERU Annual Course shaped

for industry researchers which will take

place end of October in Lucern.

The MatLife Travelling Lab Workshop

(TLab) will provide academic and industrial

participants hand-on experience with new

functional materials and systems in a

clinical and industrial perspective.

A workshop on Nanoanalytics organised

by the platform (NMMC) will take place in

June at Empa. The workshop will mainly

target participants from the industry but

will also be open to academic participants.

The MMNS Summer School on “Nano-

electronic circuits and tools” will take place

in July at EPFL, Lausanne. This mini-course

targets essentially PhD students.

The master thesis support programme

will be continued in 2008 and will encourage

more undergraduate students from top

foreign universities to obtain their master

thesis within a CCMX funded project.

For a full list of education and training

activities, please visit the CCMX website

(www.ccmx.ch).

A common industrial liaison model will be

applied as of 2008 by all ERUs. It addresses

both large and small companies who can

either purchase “research” tickets for parti-

cipation in research projects and for playing

a role in the decisions made in the selected

thematic area, or join Club CCMX giving

them access to education and networking

activities (see «What to know about Club

CCMX» above). Company contribution to

research tickets may comprise an in-kind

contribution together with a cash contribu-

tion. Matching funds will be provided by

CCMX once research tickets are purchased by

a company.

The industry outreach activities that are

planned for 2008 include the ERUs and

platform Science & Networking Days which

will bring together industry researchers

with the academic researchers involved in

the ERU/platform projects. These events

will be exclusively open to Club CCMX

members and to industrial partners.

MatLife will be associated to several con-

ferences including the Gordon Research

Conference (GRC) on Biointerface Science

that will take place in Aussois, France in

September 2008 and the 3rd International

Workshop on Single Cell Analysis taking

place in September in Zurich

The ERUs and the platform will be organis-

ing several Technology Aperitifs. These

5-to-7 events aim at bringing the research

activities closer to industry and thus gene-

rating creative ideas for new applications.

The first SPERU/ MatLife joint Technologi-

cal Aperitif is planned to take place in June

in Basel to foster the contacts between the

pharmaceutical and biotechnology indus-

tries and the academic institutions.

* FTE= full-time equivalent positions (status on 31st December 2007).

B. Steitz, J. Salaklang, A. Finka, C. O’Neil,

H. Hofmann, A. Petri-Fink,

Fixed Bed Reactor for Solid-Phase Surface

Derivatization of Superparamagnetic

Nanoparticles,

Bioconjugate Chemistry, 18 (2007) 1684-1690.

A. Petri-Fink, B. Steitz, A. Finka, J. Salaklang,

H. Hofmann,

Effect of cell media on polymer coated

superparamagnetic iron oxide nanoparticles

(SPIONs): colloidal stability, cytotoxicity,

and cellular uptake studies,

European Journal of Pharmaceutics and

Biopharmaceutics, 68 (2008) 129-137.

R. Tornay, T. Braschler, N. Demierre,

B. Steitz, A. Finka, H. Hofmann, J.A.

Hubbell, P. Renaud,

Dielectrophoresis-based manipulation and

surface functionalization of particles in a

microfluidic device,

Lab on a Chip, 8 (2008) 267-273.

A. Tricoli, M. Graf, S. E. Pratsinis,

Optimal doping for enhanced SnO2

Sensitivity and Thermal Stability,

Advanced Functional Materials (2008), in press.

S. Heiroth, T. Lippert, A. Wokaun, M. Döbeli,

Microstructure and electrical conductivity

of YSZ thin films prepared by pulsed laser

deposition,

submitted to Appl. Phys. A.

C. Danelon, M.G. Jenke, C. Schreiter,

G.M. Kim, J.B. Perez, C. Santschi, J. Brugger,

H. Vogel,

Micro- and nanostructured devices for the

investigation of biomolecular interactions,

Chimia, 60 (2006) A754-A760.

O. Guillaume-Gentil, Y. Akiyama, M.

Schuler, C. Tang, M. Textor, M. Yamato, T.

Okano, J. Vörös,

Polyelectrolyte coatings with a potential

for electronic control and cell sheet

engineering,

Advanced Materials,

20 (2008) 560-565.

ClubCCMX

The CCMX steering committee agreed to

continue funding 15 of the current flagship

projects following the requests for continu-

ation and the excellent results that were

shown. These projects will be running into

2008 and 2009.

A new call for proposals was launched

at the end of 2007. 22 outline proposals

were received in October 2007 and 15

full proposals were finally submitted in

January 2008. At the moment of the

writing of this report the projects are

being evaluated and the process will allow

for new projects to be funded as of April

2008. These projects will be funded ac-

cording to the new CCMX rule requiring

matching funds from the industry.

The analytical platform (NMMC) will carry out

a project entitled “Evaluation of the analytical

instrumentation within the ETH Domain”.

The goal of this survey is to establish the

situation of Analytical Instrumentation in

the ETH Domain. It will lead to the creation

of an analytical portal on the CCMX website.

Education activities planned for 2008 in-

clude the SPERU Annual Course shaped

for industry researchers which will take

place end of October in Lucern.

The MatLife Travelling Lab Workshop

(TLab) will provide academic and industrial

participants hand-on experience with new

functional materials and systems in a

clinical and industrial perspective.

A workshop on Nanoanalytics organised

by the platform (NMMC) will take place in

June at Empa. The workshop will mainly

target participants from the industry but

will also be open to academic participants.

The MMNS Summer School on “Nano-

electronic circuits and tools” will take place

in July at EPFL, Lausanne. This mini-course

targets essentially PhD students.

The master thesis support programme

will be continued in 2008 and will encourage

more undergraduate students from top

foreign universities to obtain their master

thesis within a CCMX funded project.

For a full list of education and training

activities, please visit the CCMX website

(www.ccmx.ch).

A common industrial liaison model will be

applied as of 2008 by all ERUs. It addresses

both large and small companies who can

either purchase “research” tickets for parti-

cipation in research projects and for playing

a role in the decisions made in the selected

thematic area, or join Club CCMX giving

them access to education and networking

activities (see «What to know about Club

CCMX» above). Company contribution to

research tickets may comprise an in-kind

contribution together with a cash contribu-

tion. Matching funds will be provided by

CCMX once research tickets are purchased by

a company.

The industry outreach activities that are

planned for 2008 include the ERUs and

platform Science & Networking Days which

will bring together industry researchers

with the academic researchers involved in

the ERU/platform projects. These events

will be exclusively open to Club CCMX

members and to industrial partners.

MatLife will be associated to several con-

ferences including the Gordon Research

Conference (GRC) on Biointerface Science

that will take place in Aussois, France in

September 2008 and the 3rd International

Workshop on Single Cell Analysis taking

place in September in Zurich

The ERUs and the platform will be organis-

ing several Technology Aperitifs. These

5-to-7 events aim at bringing the research

activities closer to industry and thus gene-

rating creative ideas for new applications.

The first SPERU/ MatLife joint Technologi-

cal Aperitif is planned to take place in June

in Basel to foster the contacts between the

pharmaceutical and biotechnology indus-

tries and the academic institutions.

* FTE= full-time equivalent positions (status on 31st December 2007).

B. Steitz, J. Salaklang, A. Finka, C. O’Neil,

H. Hofmann, A. Petri-Fink,

Fixed Bed Reactor for Solid-Phase Surface

Derivatization of Superparamagnetic

Nanoparticles,

Bioconjugate Chemistry, 18 (2007) 1684-1690.

A. Petri-Fink, B. Steitz, A. Finka, J. Salaklang,

H. Hofmann,

Effect of cell media on polymer coated

superparamagnetic iron oxide nanoparticles

(SPIONs): colloidal stability, cytotoxicity,

and cellular uptake studies,

European Journal of Pharmaceutics and

Biopharmaceutics, 68 (2008) 129-137.

R. Tornay, T. Braschler, N. Demierre,

B. Steitz, A. Finka, H. Hofmann, J.A.

Hubbell, P. Renaud,

Dielectrophoresis-based manipulation and

surface functionalization of particles in a

microfluidic device,

Lab on a Chip, 8 (2008) 267-273.

A. Tricoli, M. Graf, S. E. Pratsinis,

Optimal doping for enhanced SnO2

Sensitivity and Thermal Stability,

Advanced Functional Materials (2008), in press.

S. Heiroth, T. Lippert, A. Wokaun, M. Döbeli,

Microstructure and electrical conductivity

of YSZ thin films prepared by pulsed laser

deposition,

submitted to Appl. Phys. A.

C. Danelon, M.G. Jenke, C. Schreiter,

G.M. Kim, J.B. Perez, C. Santschi, J. Brugger,

H. Vogel,

Micro- and nanostructured devices for the

investigation of biomolecular interactions,

Chimia, 60 (2006) A754-A760.

O. Guillaume-Gentil, Y. Akiyama, M.

Schuler, C. Tang, M. Textor, M. Yamato, T.

Okano, J. Vörös,

Polyelectrolyte coatings with a potential

for electronic control and cell sheet

engineering,

Advanced Materials,

20 (2008) 560-565.

ClubCCMX

M.G. Jenke, C. Schreiter, G.M. Kim, H.

Vogel, J. Brugger,

Micropositioning and microscopic

observation of individual picoliter-sized

containers within SU-8 microchannels,

Microfluidics and Nanofluidics, 3 (2007)

189-194.

M. Ochsner, M.R. Dusseiller, H.M. Grandin,

S. Luna-Morris, M. Textor, V. Vogel,

M.L. Smith,

Micro-well arrays for 3D shape control and

high resolution analysis of single cells,

Lab on a Chip, 7 (2007)1074 -1077.

S.T. Reddy, M.A. Swartz, J.A. Hubbell,

Targeting dendritic cells with biomaterials:

developing the next generation of vaccines,

Trends Immunol., 27 (2006) 573-579.

S.T. Reddy, A.J. van der Vlies, E. Simeoni,

V. Angeli, G.J. Randolph, C.P. O’Neill, L.K.

Lee, M.A. Swartz, J.A. Hubbell,

Exploiting lymphatic transport and

complement activation in nanoparticle

vaccines,

Nature Biotechnology, 25 (2007) 1159-1164.

E. Reimhult, K. Kumar,

Membrane biosensor platforms using

nano- and microporous supports,

Trends Biotechnol., 26 (2007) 82-89.

M.A. Swartz, J.A. Hubbell, S.T. Reddy,

Lymphatic drainage function and its

immunological implications: From

dendritic cell homing to vaccine design,

Seminars in Immunology (2008), in press.

A.-K. Born, M. Rottmar, A. Bruinink, K.

Maniura-Weber,

Correlating cell architecture with osteo-

genesis: first steps towards live single cell

monitoring,

submitted to European Cells & Materials

Journal.

D. Grieshaber, R. MacKenzie, J. Vörös,

E. Reimhult,

Electrochemical Biosensors – Sensor

Principles and Architectures,

submitted to Sensors.

C. Merz, W. Knoll, M. Textor, E. Reimhult,

Formation of supported bacterial lipid

membrane mimics,

submitted to Biointerphases.

T. Rhaman Khan, H.M. Grandin,

A.N. Morozov, A. Mashaghi, M. Textor,

E. Reimhult, I. Reviakine,

Lipid redistribution in phosphatidylserine-

containing vesicles adsorbing on titania,

C. Hierold, A. Jungen, C. Stampfer, T. Helbling,

Nano electromechanical sensors based on

carbon nanotubes,

Sensors and Actuators A: Physical,

136 (2007) 51-61.

K. Lee, B. Lukic, A. Magrez, J.W. Seo,

G.A.D. Briggs, A.J. Kulik, L. Forro,

Diameter-Dependent Elastic Modulus

Supports the Metastable-Catalyst Growth

of Carbon Nanotubes,

Nano Letters, 7 (2007) 1598-1602.

U. Lehmann, D. de Courten, C. Vandevyver,

V.K. Parashar, M.A.M. Gijs,

On-chip antibody handling and colorimetric

detection in a magnetic droplet manipula-

tion system,

Microelectronic Engineering, 84 (2007)

1669-1672.

A. Magrez, J.W. Seo, V.L. Kuznetsov, L. Forro,

Evidence of an equimolar C2H2-CO2

reaction in the synthesis of carbon

nanotubes,

Angewandte Chemie-International Edition,

46 (2007) 441-444.

L. Malin, I. Stolitchnov, N. Setter,

Ferroelectric polymer gate on AlGaN/GaN

Heterostructure,

J. Appl. Phys., 102 (2007) 114101.

S. Olliges, P.A. Gruber, V. Auzelyte,

Y. Ekinci, H.H. Solak, R. Spolenak,

Tensile Strength of Gold Nanointercon-

nects without the Influence of Strain

Gradients,

Acta Materialia, 55 (2007) 5201-5210.

S. Olliges, P.A. Gruber, S.N. Orso,

V. Auzelyte, Y. Ekinci, H.H. Solak, R. Spolenak,

In situ Observation of Cracks in Gold

Nano-interconnects on Flexible Substrates,

Scripta Materialia, 58 (2008) 175-178.

B. Städler, H.H. Solak, S. Frerker, K. Bonroy,

F. Frederix, J. Vörös, H.M. Grandin,

Nanopatterning of gold colloids for

label-free biosensing,

Nanotechnology, 18 (2007) 155306.

C. Stampfer, T. Helbling, A. Jungen,

C. Hierold,

Micromachined pressure sensors for

electromechanical characterization of

carbon nanotubes,

Physica Status Solidi B, 243 (2006)

3537-3541.

C. Stampfer, T. Helbling, D. Obergfell, B.

Schoberle, M.K. Tripp, A. Jungen, S. Roth,

V.M. Bright, C. Hierold,

Fabrication of single-walled carbon-nano-

tube-based pressure sensors,

Nano Letters, 6 (2006) 233-237.

I. Stolichnov, L. Malin, P. Muralt, N. Setter,

Non-volatile gate effect in the PZT/AlGaN/

GaN heterostructure,

Journal of the European Ceramic Society,

27 (2007) 4307-4311.

Report LSI,

Nikkei Microdevices, November 2007,

p. 114.

U. Lehmann, M. Sergio, S. Pietrocola,

E. Dupont, C. Niclass, M.A.M. Gijs,

E. Charbon,

Microparticle photometry in a CMOS

microsystem combining magnetic

actuation and in-situ optical detection,

Sensors and Actuators B (2007),

in press.

K.E. Moselund, D. Bouvet, M.H. Ben

Jamaa, D. Atienza, Y. Leblebici, G. De

Micheli, A.M. Ionescu,

Prospects for Logic-On-A-Wire,

Microelectronic Engineering (2008), in press.

R. MacKenzie, D. Grieshaber, J. Vörös,

E. Reimhult,

submitted to J. Appl. Phys.

B. Städler, M. Limacher, N. Li, J. Vörös,

Photobleaching Induced Damage of Bio-

molecules : Streptavidin as ‘Bio’-Photoresist,

submitted to ChemPhysChem.

B. Fan, R. Hany, J.-E Moser, F. Nüesch,

Enhanced cyanine solar cell performance

upon oxygen doping,

Org. Electr., 9 (2008) 85-94.

P. Pittet, L. Kyumin, A. Kulik, J.-J. Meister,

B. Hinz,

Fibrogenic fibroblasts increase intercel-

lular adhesion strength by reinforcing

individual OB-cadherin bonds,

J Cell Sci., 121 (2008) 877-886.

P.-J. Wipff, D.B. Rifkin, J.J. Meister, B. Hinz,

Myofibroblast contraction activates TGFß1

from the extracellular matrix,

J Cell Biol., 179 (2007) 1311-1323.

D. Bayat, T. Akiyama, N. F. de Rooij, U. Staufer,

Dynamic behavior of the tuning fork AFM probe,

D. Crespy, R.M. Rossi, D. Reiss, P. Schmutz,

M. Heuberger, J.F. Lübben,

AFM Investigations of a Smart Tempera-

ture and Humidity Responsive Film,

submitted to Macromolecular Rapid Com-

munications.

A. Geiser, F. Bin, H. Benmansour, J. Heier,

B. Keller, F. Nüesch, R. Hany,

Poly(3-hexylthiophene) / C60 Heterojunc-

tion Solar Cells: Implication of Morphol-

ogy on Performance and Ambipolar

Charge Collection,

submitted to Adv. Func. Mat.

S. Hochstrasser(-Kurz), T.Suter, D.Reiss,

C. Latkoczy, D. Günther, S. Virtanen,

P.J. Uggowitzer, P. Schmutz,

ICP-MS, SKPFM, XPS and microcapillary

investigation of the local corrosion

mechanisms of WC-Co hardmetal,

submitted to J. Electrochem. Soc.

P. Schmutz, D.Reiss, P.J. Uggowitzer,

S. Virtanen,

Microscale investigation of surface

reactivity and corrosion initiation proc-

esses of Mg-Al-Zn (AZ91) Alloy,

P.-J. Wipff, B. Hinz,

Integrins and the activation of latent

transforming growth factor ß1 - an

intimate relationship,

submitted to Eur. J. Cell Biol.

M.G. Jenke, C. Schreiter, G.M. Kim, H.

Vogel, J. Brugger,

Micropositioning and microscopic

observation of individual picoliter-sized

containers within SU-8 microchannels,

Microfluidics and Nanofluidics, 3 (2007)

189-194.

M. Ochsner, M.R. Dusseiller, H.M. Grandin,

S. Luna-Morris, M. Textor, V. Vogel,

M.L. Smith,

Micro-well arrays for 3D shape control and

high resolution analysis of single cells,

Lab on a Chip, 7 (2007)1074 -1077.

S.T. Reddy, M.A. Swartz, J.A. Hubbell,

Targeting dendritic cells with biomaterials:

developing the next generation of vaccines,

Trends Immunol., 27 (2006) 573-579.

S.T. Reddy, A.J. van der Vlies, E. Simeoni,

V. Angeli, G.J. Randolph, C.P. O’Neill, L.K.

Lee, M.A. Swartz, J.A. Hubbell,

Exploiting lymphatic transport and

complement activation in nanoparticle

vaccines,

Nature Biotechnology, 25 (2007) 1159-1164.

E. Reimhult, K. Kumar,

Membrane biosensor platforms using

nano- and microporous supports,

Trends Biotechnol., 26 (2007) 82-89.

M.A. Swartz, J.A. Hubbell, S.T. Reddy,

Lymphatic drainage function and its

immunological implications: From

dendritic cell homing to vaccine design,

Seminars in Immunology (2008), in press.

A.-K. Born, M. Rottmar, A. Bruinink, K.

Maniura-Weber,

Correlating cell architecture with osteo-

genesis: first steps towards live single cell

monitoring,

submitted to European Cells & Materials

Journal.

D. Grieshaber, R. MacKenzie, J. Vörös,

E. Reimhult,

submitted to Sensors.

C. Merz, W. Knoll, M. Textor, E. Reimhult,

Formation of supported bacterial lipid

membrane mimics,

T. Rhaman Khan, H.M. Grandin,

A.N. Morozov, A. Mashaghi, M. Textor,

E. Reimhult, I. Reviakine,

Lipid redistribution in phosphatidylserine-

containing vesicles adsorbing on titania,

C. Hierold, A. Jungen, C. Stampfer, T. Helbling,

Nano electromechanical sensors based on

carbon nanotubes,

Sensors and Actuators A: Physical,

136 (2007) 51-61.

K. Lee, B. Lukic, A. Magrez, J.W. Seo,

G.A.D. Briggs, A.J. Kulik, L. Forro,

Diameter-Dependent Elastic Modulus

Supports the Metastable-Catalyst Growth

of Carbon Nanotubes,

Nano Letters, 7 (2007) 1598-1602.

U. Lehmann, D. de Courten, C. Vandevyver,

V.K. Parashar, M.A.M. Gijs,

On-chip antibody handling and colorimetric

detection in a magnetic droplet manipula-

tion system,

Microelectronic Engineering, 84 (2007)

1669-1672.

A. Magrez, J.W. Seo, V.L. Kuznetsov, L. Forro,

Evidence of an equimolar C2H2-CO2

reaction in the synthesis of carbon

nanotubes,

Angewandte Chemie-International Edition,

46 (2007) 441-444.

L. Malin, I. Stolitchnov, N. Setter,

Ferroelectric polymer gate on AlGaN/GaN

Heterostructure,

J. Appl. Phys., 102 (2007) 114101.

S. Olliges, P.A. Gruber, V. Auzelyte,

Y. Ekinci, H.H. Solak, R. Spolenak,

Tensile Strength of Gold Nanointercon-

nects without the Influence of Strain

Gradients,

Acta Materialia, 55 (2007) 5201-5210.

S. Olliges, P.A. Gruber, S.N. Orso,

V. Auzelyte, Y. Ekinci, H.H. Solak, R. Spolenak,

In situ Observation of Cracks in Gold

Nano-interconnects on Flexible Substrates,

Scripta Materialia, 58 (2008) 175-178.

B. Städler, H.H. Solak, S. Frerker, K. Bonroy,

F. Frederix, J. Vörös, H.M. Grandin,

Nanopatterning of gold colloids for

label-free biosensing,

Nanotechnology, 18 (2007) 155306.

C. Stampfer, T. Helbling, A. Jungen,

C. Hierold,

Micromachined pressure sensors for

electromechanical characterization of

carbon nanotubes,

Physica Status Solidi B, 243 (2006)

3537-3541.

C. Stampfer, T. Helbling, D. Obergfell, B.

Schoberle, M.K. Tripp, A. Jungen, S. Roth,

V.M. Bright, C. Hierold,

Fabrication of single-walled carbon-nano-

tube-based pressure sensors,

Nano Letters, 6 (2006) 233-237.

I. Stolichnov, L. Malin, P. Muralt, N. Setter,

Non-volatile gate effect in the PZT/AlGaN/

GaN heterostructure,

Journal of the European Ceramic Society,

27 (2007) 4307-4311.

Report LSI,

Nikkei Microdevices, November 2007,

p. 114.

U. Lehmann, M. Sergio, S. Pietrocola,

E. Dupont, C. Niclass, M.A.M. Gijs,

E. Charbon,

Microparticle photometry in a CMOS

microsystem combining magnetic

actuation and in-situ optical detection,

Sensors and Actuators B (2007),

in press.

K.E. Moselund, D. Bouvet, M.H. Ben

Jamaa, D. Atienza, Y. Leblebici, G. De

Micheli, A.M. Ionescu,

Prospects for Logic-On-A-Wire,

R. MacKenzie, D. Grieshaber, J. Vörös,

E. Reimhult,

submitted to J. Appl. Phys.

B. Städler, M. Limacher, N. Li, J. Vörös,

Photobleaching Induced Damage of Bio-

molecules : Streptavidin as ‘Bio’-Photoresist,

submitted to ChemPhysChem.

B. Fan, R. Hany, J.-E Moser, F. Nüesch,

Enhanced cyanine solar cell performance

upon oxygen doping,

Org. Electr., 9 (2008) 85-94.

P. Pittet, L. Kyumin, A. Kulik, J.-J. Meister,

B. Hinz,

Fibrogenic fibroblasts increase intercel-

lular adhesion strength by reinforcing

individual OB-cadherin bonds,

J Cell Sci., 121 (2008) 877-886.

P.-J. Wipff, D.B. Rifkin, J.J. Meister, B. Hinz,

Myofibroblast contraction activates TGFß1

from the extracellular matrix,

J Cell Biol., 179 (2007) 1311-1323.

D. Bayat, T. Akiyama, N. F. de Rooij, U. Staufer,

Dynamic behavior of the tuning fork AFM probe,

D. Crespy, R.M. Rossi, D. Reiss, P. Schmutz,

M. Heuberger, J.F. Lübben,

AFM Investigations of a Smart Tempera-

ture and Humidity Responsive Film,

submitted to Macromolecular Rapid Com-

munications.

A. Geiser, F. Bin, H. Benmansour, J. Heier,

B. Keller, F. Nüesch, R. Hany,

Poly(3-hexylthiophene) / C60 Heterojunc-

tion Solar Cells: Implication of Morphol-

ogy on Performance and Ambipolar

Charge Collection,

submitted to Adv. Func. Mat.

S. Hochstrasser(-Kurz), T.Suter, D.Reiss,

C. Latkoczy, D. Günther, S. Virtanen,

P.J. Uggowitzer, P. Schmutz,

ICP-MS, SKPFM, XPS and microcapillary

investigation of the local corrosion

mechanisms of WC-Co hardmetal,

P. Schmutz, D.Reiss, P.J. Uggowitzer,

S. Virtanen,

Microscale investigation of surface

reactivity and corrosion initiation proc-

esses of Mg-Al-Zn (AZ91) Alloy,

P.-J. Wipff, B. Hinz,

Integrins and the activation of latent

transforming growth factor ß1 - an

intimate relationship,

submitted to Eur. J. Cell Biol.

Development of novel methods for surface modification and investigation of cell-particles interaction for superparamagnetic nanoparticles (PAPAMOD)

Nanocrystalline ceramic thin film coating without sintering (NANCER)

Smart functional foams

Zero order nano optical pigments (ZONOP)

Photochemically functionalizable scaffolds for Tissue Engineering andNerve Regeneration

Immunofunctional Nanoparticles

Multivalent Lectin Array: A Combinatorial Approach

Bio-functionalized, biodegradable nanostructured magnesium implant forbiomedical applications

Three-Dimensionally Designed Cell Cultures Consisting of MicrostructuredCell-Sheets and Polymer Layers for Tissue Engineering

Platform for high-density parallel screening of membrane receptor function

Studying Single Cells in Engineered 3D Microenvironments

Biopolymer PHA as surface material for micropatterning proteins on microarrays

Lab-on-a-chip for analysis and diagnostics

Materials, devices and design technologies for nanoelectronic systemsbeyond ultimately scaled CMOS

Development and characterization of nanowires for applications in bio-electronics

Biochemical nanofactory

Development of Self-Sensing and -Actuating Probe for Dynamic ModeAFM at Cryogenic Temperature

New Generation Scanning Anode Field Emission Microscope at EMPA Thun

Nano-XAS

Efficient double-passage SNOMs

Correlated Energy Electron Loss and Cathodoluminescene spectrometry in SPTEM

Scanning Probe Microscopy of Cytoskeletal Proteins in Living Cells

Swiss SPM User laboratory

Nanometric level investigations of Aluminum Nitride/Silicon Nitride hardcoatings using High Resolution TEM and Energy Dispersive X-Ray analysis

Subattonewton force sensors with hard magnetic tips for magneticresonance force microscopy

Stress voiding and electromigration as reliability indicator in nanoscaled interconnects

AMORTEM:FIB Preparation of TEM-Specimens with Minimized Defects

Prof. Karen Scrivener [email protected]

Prof. Heinrich HofmannEPFL - [email protected]

Prof. Marcus TextorETH Zurich - [email protected]

Dr. Nathalie JongenCommunications and liaison [email protected]

Dr. Nathalie JongenManaging [email protected]

Dr. Géraldine CoullerezScientific and industrial liaison [email protected]

Kathleen [email protected]

Dr. Niklaus BühlerScientific and industrial liaison [email protected]

Development of novel methods for surface modification and investigation of cell-particles interaction for superparamagnetic nanoparticles (PAPAMOD)

Nanocrystalline ceramic thin film coating without sintering (NANCER)

Smart functional foams

Zero order nano optical pigments (ZONOP)

Photochemically functionalizable scaffolds for Tissue Engineering andNerve Regeneration

Immunofunctional Nanoparticles

Multivalent Lectin Array: A Combinatorial Approach

Bio-functionalized, biodegradable nanostructured magnesium implant forbiomedical applications

Three-Dimensionally Designed Cell Cultures Consisting of MicrostructuredCell-Sheets and Polymer Layers for Tissue Engineering

Platform for high-density parallel screening of membrane receptor function

Studying Single Cells in Engineered 3D Microenvironments

Biopolymer PHA as surface material for micropatterning proteins on microarrays

Lab-on-a-chip for analysis and diagnostics

Materials, devices and design technologies for nanoelectronic systemsbeyond ultimately scaled CMOS

Development and characterization of nanowires for applications in bio-electronics

Biochemical nanofactory

Development of Self-Sensing and -Actuating Probe for Dynamic ModeAFM at Cryogenic Temperature

New Generation Scanning Anode Field Emission Microscope at EMPA Thun

Nano-XAS

Efficient double-passage SNOMs

Correlated Energy Electron Loss and Cathodoluminescene spectrometry in SPTEM

Scanning Probe Microscopy of Cytoskeletal Proteins in Living Cells

Swiss SPM User laboratory

Nanometric level investigations of Aluminum Nitride/Silicon Nitride hardcoatings using High Resolution TEM and Energy Dispersive X-Ray analysis

Subattonewton force sensors with hard magnetic tips for magneticresonance force microscopy

Stress voiding and electromigration as reliability indicator in nanoscaled interconnects

AMORTEM:FIB Preparation of TEM-Specimens with Minimized Defects

Prof. Karen Scrivener [email protected]

Prof. Heinrich HofmannEPFL - [email protected]

Prof. Marcus TextorETH Zurich - [email protected]

Dr. Nathalie JongenCommunications and liaison [email protected]

Dr. Nathalie JongenManaging [email protected]

Dr. Géraldine CoullerezScientific and industrial liaison [email protected]

Kathleen [email protected]

Dr. Niklaus BühlerScientific and industrial liaison [email protected]

Prof. Giovanni De MicheliEPFL - [email protected]

Prof. Michel RappazEPFL - [email protected]

Dr. Anil LeblebiciScientific and industrial liaison [email protected]

Prof. Hans Josef HugEmpa - [email protected]

Chiara CorticelliScientific and industrial liaison [email protected]

Prof. Eduard Arzt (Saarland University)

Prof. David Grainger (University of Utah)

Prof. Philippe Marcus (Ecole Nationale Supérieure de Chimie)

Prof. Klaus Müller (F. Hoffmann-La Roche Ltd)

Prof. Karen Scrivener (EPFL) - Chair

Dr. Jacques Baur (Rolex)

Prof. Peter Chen (ETH Zurich)

Dr. Pierangelo Gröning (Empa)

Dr. Thomas Hinderling (CSEM)

Prof. Jan-Anders Månson (EPFL)

Dr. Hans-Walter Schläpfer (Sulzer)

Prof. Ralph Spolenak (ETH Zurich)

Prof. Friso van der Veen (PSI)

Annual Report 2007

Prof. Giovanni De MicheliEPFL - [email protected]

Prof. Michel RappazEPFL - [email protected]

Dr. Anil LeblebiciScientific and industrial liaison [email protected]

Prof. Hans Josef HugEmpa - [email protected]

Chiara CorticelliScientific and industrial liaison [email protected]

Prof. Eduard Arzt (Saarland University)

Prof. David Grainger (University of Utah)

Prof. Philippe Marcus (Ecole Nationale Supérieure de Chimie)

Prof. Klaus Müller (F. Hoffmann-La Roche Ltd)

Prof. Karen Scrivener (EPFL) - Chair

Dr. Jacques Baur (Rolex)

Prof. Peter Chen (ETH Zurich)

Dr. Pierangelo Gröning (Empa)

Dr. Thomas Hinderling (CSEM)

Prof. Jan-Anders Månson (EPFL)

Dr. Hans-Walter Schläpfer (Sulzer)

Prof. Ralph Spolenak (ETH Zurich)

Prof. Friso van der Veen (PSI)

Annual Report 2007

www.ccmx.ch

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ccmx annual activity report 2007

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